US9181559B2

US9181559B2 - Generation of high polyhydroxybutyrate producing oilseeds

Info

Publication number: US9181559B2
Application number: US13/395,702
Authority: US
Inventors: Nii Patterson; Jihong Tang; Jixiang Han; Venkata Tavva; Andrew Hertig; Zhigang Zhang; Thomas Martin Ramseier; Karen Bohmert-Tatarev; Oliver P. Peoples; Kristi D. Snell
Original assignee: Metabolix Inc
Current assignee: Yield10 Bioscience Inc
Priority date: 2009-09-15
Filing date: 2010-09-15
Publication date: 2015-11-10
Also published as: AU2010295638A1; US20120174253A1; BR112012005591A2; CA2773707A1; EP2477477A1; WO2011034945A1; WO2011034946A9; CA2773703A1; US20120180162A1; WO2011034946A1; EP2478105A1; AU2010295637A1; BR112012005592A2; AU2010295637B2

Abstract

Transgenic plants, plant material, plant cells, and genetic constructs for synthesis of biopolymers, for example polyhydroxyalkanoates (“PHA”) are provided. In one embodiment, the transgenic plants synthesize polyhydroxybutyrate (“PHB”). In one embodiment the transgenic plant encodes siRNA for one or more of the genes encoding enzymes for producing PHA. In a more preferred embodiment, the siRNA expression is under the control of an inducible regulatory element. In another embodiment, the transgenic plant contains transgenes that encode expression enzymes that will degrade the polymer. In a preferred embodiment, the expression of these enzymes is under the control of a germination specific, inducible, or minimal promoter. In another embodiment, the transgenic plant contains transgenes encoding enzymes that increase carbon flow for polymer synthesis. In a preferred embodiment, these transgenes encode enzymes that increase carbon flow in the Calvin Cycle.

Description

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a filing under 35 U.S.C. §371 of PCT/US2010/048963 filed with the Patent Cooperation Treaty on Sep. 15, 2010, which claims priority to and benefit of U.S. Provisional Application No. 61/242,522, filed Sep. 15, 2009, all of which are herein incorporated in their entirety by reference.

REFERENCE TO SEQUENCE LISTING

The Sequence Listing submitted Mar. 13, 2012, as a text file named “MBX_—078_ST25.txt,” created on Sep. 15, 2010, and having a size of 244 Kilo bytes is hereby incorporated by reference.

FIELD OF THE INVENTION

The invention is generally related to the field of polymer production in transgenic plants. Methods for generating industrial oilseeds producing high levels of polyhydroxybutyrate (PHB) and industrial oilseeds producing high levels of PHB are described.

BACKGROUND OF THE INVENTION

Production of polyhydroxyalkanoates (PHAs), a family of naturally occurring renewable and biodegradable plastics, in crops has the potential of providing a renewable source of polymers, chemical intermediates and bio-energy from one crop if plant residues remaining after polymer isolation are converted to liquid fuels and/or energy. PHAs can provide an additional revenue stream that would make bioenergy crops more economically viable.

PHAs are a natural component of numerous organisms in multiple ecosystems and accumulate in a wide range of bacteria as a granular storage material when the microbes are faced with an unfavorable growth environment, such as a limitation in an essential nutrient (Madison et al., Microbiol. Mol. Biol. Rev., 1999, 63, 21-53; Suriyamongkol et al., Biotechnol Adv, 2007, 25, 148-175). The monomer unit composition of these polymers is largely dictated by available carbon source as well as the native biochemical pathways present in the organism. Today PHAs are produced industrially from renewable resources in bacterial fermentations providing an alternative to plastics derived from fossil fuels. PHAs possess properties enabling their use in a variety of applications currently served by petroleum-based plastics and are capable of matching or exceeding the perfounance characteristics of fossil fuel derived plastics with a broad spectrum of properties that can be obtained by varying the monomer composition of homo- and co-polymers, or by manipulating properties such as molecular weight (Sudesh et al., Prog. Polym. Sci., 2000, 25, 1503-1555; Sudesh et al., CLEAN—Soil, Air, Water, 2008, 36, 433-442).

Industrial production of PHAs in crop plants would provide a low cost, renewable source of plastics. Production of PHAs in plants has been an as yet unsolved goal for plant scientists and has previously been demonstrated in a number of crops unsuitable for industrial production or in industrially useful crops at levels to low to be commercially attractive [for review, see (Suriyamongkol et al., Biotechnol Adv, 2007, 25, 148-175); (van Beilen et al., The Plant Journal, 2008, 54, 684-701) and references within] including maize (Poirier et al., 2002, Polyhydroxyalkanoate production in transgenic plants, in Biopolymers, Vol 3a, Steinbuchel, A. (ed), Wiley-VHC Verlag GmbH, pgs 401-435), sugarcane (Purnell et al., Plant Biotechnol. J., 2007, 5, 173-184), switchgrass (Somleva et al., Plant Biotechnol J, 2008, 6, 663-678), flax (Wrobel et al., J. Biotechnol., 2004, 107, 41-54; Wrobel-Kwiatkowsk et al., Biotechnol Prog, 2007, 23, 269-277), cotton (John et al., Proceedings of the National Academy of Sciences of the United States of America, 1996, 93, 12768-12773), alfalfa (Small et al., Crop Set., 2002, 42, 919-927), tobacco (Arai et al., Plant Biotechnol., 2001, 18, 289-293; Bohmert et al., Plant Physiol., 2002, 128, 1282-1290; Lossl et al., Plant Cell Reports, 2003, 21, 891-899; Lössl et al., Plant Cell Physiol, 2005, 46, 1462-1471), potato (Bohmert et al., Plant Physiol., 2002, 128, 1282-1290), and oilseed rape (Valentin et al., Int. J. Biol. Macromol., 1999, 25, 303-306; Slater et al., Nat. Biotechnol., 1999, 17, 1011-1016.). Most of the efforts to produce PHAs in plants have focused on production of the homopolymer P3HB or the copolymer poly-3-hydroxybutyrate-co-3-hydroxyvalerate (P3HBV). While there have been some efforts to produce medium chain length PHAs in plants, these studies have yielded barely detectable levels of polymer (Romano et al., Planta, 2005, 220, 455-464; Mittendorf et al., Proceedings of the National Academy of Sciences of the United States of America, 1998, 95, 13397-13402; Poirier et al., Plant Physiol., 1999, 121, 1359-1366; Matsumoto, Journal of Polymers and the Environment, 2006, 14, 369-374; Wang et al., Chinese Science Bulletin, 2005, 50, 1113-1120).

To date, the highest levels of polymer have been obtained when the homopolymer poly-3-hydroxybutyrate (P3HB or PHB) is produced in plastids (Suriyamongkol et al., Biotechnol Adv, 2007, 25, 148-175; van Beilen et al., The Plant Journal, 2008, 54, 684-701; Bohmert et al., Molecular Biology and Biotechnology of Plant Organelles, 2004, 559-585). This is likely due to the high flux of acetyl-CoA, the precursor for PHB in these organelles during fatty acid biosynthesis (Bohmert et al., Molecular Biology and Biotechnology of Plant Organelles, 2004, 559-585). Expression of three genes encoding β-ketothiolase, acetoacetyl CoA reductase, and PHA synthase, allows the conversion of acetyl-CoA within the plastid to PHB. Previous work has reported producing levels of PHB in Brassica napus up to a maximum of 7.7% of seed weight, a level too low for commercial production

Therefore, it is an object of the invention to provide methods and compositions for producing transgenic oilseeds having commercially viable levels of polyhydroxyalkanoates in the seed, for example greater than 7%, 10%, 15%, or 19% polyhydroxyalkanoate or more of the total dry seed weight and capable of germinating.

SUMMARY OF THE INVENTION

Transgenic oilseed plants, plant material, plant cells, and genetic constructs for synthesis of polyhydroxyalkanoates (“PHA”) are provided. In the preferred embodiment, the transgenic oilseed plants synthesize polyhydroxybutyrate (“PHB”) in the seed. Host plants, plant tissue, and plant material have been engineered to express genes encoding enzymes in the biosynthetic pathway for PHB production such that polymer precursors in the plastid are polymerized to polymer. Genes utilized include phaA, phaB, phaC, all of which are known in the art. The genes can be introduced in the plant, plant tissue, or plant cell using conventional plant molecular biology techniques.

It has been discovered, using a different screening method to identify transgenic lines than those used in all other reported studies, that very high levels of PHB can be produced in the oilseed but that oilseeds with high levels of PHB fail to germinate or germinate but produce impaired seedlings which do not survive to produce viable fertile plants. The failure to produce viable progeny explains why previous researchers failed to demonstrate that commercial levels of PHB can be produced in transgenic oilseeds.

In one embodiment the transgenes encoding PHA biosynthesis are expressed in a seed specific manner such that the PHA accumulates in the seed. In this embodiment it is preferred that the level of PHA accumulated is greater than %, 8%, 9%, 10%, 11%, 12%, 13%. 14%, 15%, 16%, 17%, 18% and 19% of the dry weight of the seed. In another embodiment these transgenic oilseeds encode one or more additional transgenes to improve the germination efficiency of high PHA producing oilseeds where the level of PHA in the oilseed is greater than 8% by weight and where the seeds germinate to at least 10%, 20%, 40%, 60%, 80%, 90%, 100% of the level of seeds from the unmodified parental line or seeds with low levels of PHA.

These additional transgenes can encode siRNA for one or more of the genes encoding enzymes for producing PHA. These additional transgenes can encode one or more genes involved in the PHA degradation pathway. These additional transgenes can encode one or more enzymes involved in photosynthesis pathways. In a more preferred embodiment, these additional transgenes can be expressed under the control of an inducible regulatory element or promoter. In another embodiment, these additional transgenes can be placed under the control of a minimal promoter such that very low levels of expression are obtained. In another embodiment, these additional transgenes can be placed under the control of a germination specific promoter, such as the promoter from Vigna mungo sulphydryl-endopeptidase gene (SH-EP promoter; Akasofu et al., 1990 Nucleic Acids Research. 18, 1892). In another embodiment the transgenic oilseed may encode combinations of these additional transgenes, for example transgenes encoding siRNA plus transgenes encoding one of more enzymes involved in photosynthesis pathways. Other combinations of the additional transgenes or other transgenes and approaches to solving this previously unknown problem will be obvious to those skilled in the art.

Transgenic plants useful for the invention include dicots or monocots. Preferred host plants are oilseed plants, but are not limited to members of the Brassica family including B. napus, B. rapa, B. carinata and B. juncea; industrial oilseeds such as Camelina sativa, Crambe, Jatropha, castor; Arabidopsis thaliana; Calendula, Cuphea; maize; soybean; cottonseed; sunflower; palm; coconut; safflower; peanut; mustards including Sinapis alba; and tobacco.

Other embodiments provide plant material and plant parts of the transgenic plants including seeds, flowers, stems, and leaves. The oilseeds can be used for the extraction of PHA biopolymer or as a source of PHA biopolymer based chemical intermediates. The residual parts of the seed can be used as meal for animal feed or steam and power generation and a source of vegetable oil for industrial oelochemicals or biofuel.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram describing an ecdysone inducible promoter system.

FIG. 2 is a bar graph showing percent PHB content in select T2 and T3 PHB producing seeds obtained from transformations of vectors containing the PHB pathway genes and a cassette for siRNA to either the thiolase or synthase gene. A lines were obtained from transformations with vector pPhaA-RNAi/35S. B lines were obtained from transformations with vector pPhaA-RNAi/glyP. C lines were obtained from transformations with vector pPhaC-RNAi/35S. D lines were obtained from transformations with vector pPhaC-RNAi/glyP.

FIG. 3 is a schematic diagram describing a strategy for using a polymer degradation pathway to enable seed germination.

FIG. 4 is a bar graph showing percent PHB content in select T2 and T3 PHB producing seeds obtained from transformations of vector pMBXVT1 containing the PHB pathway genes expressed under the control of seed specific promoters and expression cassettes for a degradation pathway consisting of depolymerase and dehydrogenase expressed under the control of a germination specific promoter.

FIG. 5 is a schematic diagram describing a strategy for creating hybrid seeds using cytoplasmic male sterility.

FIG. 6 is a protein sequence alignment of FBPase/SBPase genes in transformation vectors pMBXS407 and pMBXS408. Vector pMBXS407 contains a gene encoding a FBPase/SBPase with 100% homology to the FBPase/SBPase protein from Synechococcus elongatus PCC 7942 listed in accession CP000100. Transformation vector pMBXS408 contains a gene encoding a FBPase/SBPase with 100% homology to the FBPase/SBPase protein from Synechococcus elongatus PCC 7942 listed in accession D83512.

DETAILED DESCRIPTION OF THE INVENTION Definitions

Unless otherwise indicated, the disclosure encompasses all conventional techniques of plant breeding, microbiology, cell biology and recombinant DNA, which are within the skill of the art. See, e.g., Sambrook and Russell, Molecular Cloning: A Laboratory Manual, 3rd edition (2001); Current Protocols In Molecular Biology [(F. M. Ausubel, et al. eds., (1987)]; Plant Breeding Principles and Prospects (Plant Breeding, Vol 1) M. D. Hayward, N. O. Bosemark, I. Romagosa; Chapman & Hall, (1993.); Coligan, Dunn, Ploegh, Speicher and Wingfeld, eds. (1995) Current Protocols in Protein Science (John Wiley & Sons, Inc.); the series Methods in Enzymology (Academic Press, Inc.): PCR 2: A Practical Approach (M. J. MacPherson, B. D. Hames and G. R. Taylor eds. (1995)].

Unless otherwise noted, technical terms are used according to conventional usage. Definitions of common terms in molecular biology may be found in Lewin, Genes VII, published by Oxford University Press, 2000; Kendrew et al. (eds.), The Encyclopedia of Molecular Biology, published by Wiley-Interscience, 1999; and Robert A. Meyers (ed.), Molecular Biology and Biotechnology, a Comprehensive Desk Reference, published by VCH Publishers, Inc., 1995; Ausubel et al. (1987) Current Protocols in Molecular Biology, Green Publishing; Sambrook and Russell. (2001) Molecular Cloning: A Laboratory Manual 3rd. edition.

A number of terms used herein are defined and clarified in the following section.

The term PHB refers to polyhydroxybutyrate and is used interchangeably with the term PHA which refers to polyhydroxyalkanoate.

The term PHB also encompasses copolymers of hydroxybutyrate with other hydroxyacid monomers.

The term “PHA copolymer” refers to a polymer composed of at least two different hydroxyalkanoic acid monomers.

The term “PHA homopolymer” refers to a polymer that is composed of a single hydroxyalkanoic acid monomer.

As used herein, a “vector” is a replicon, such as a plasmid, phage, or cosmid, into which another DNA segment may be inserted so as to bring about the replication of the inserted segment. The vectors can be expression vectors.

As used herein, an “expression vector” is a vector that includes one or more expression control sequences

As used herein, an “expression control sequence” is a DNA sequence that controls and regulates the transcription and/or translation of another DNA sequence. Control sequences that are suitable for prokaryotes, for example, include a promoter, optionally an operator sequence, a ribosome binding site, and the like. Eukaryotic cells are known to utilize promoters, polyadenylation signals, and enhancers.

As used herein, “operably linked” means incorporated into a genetic construct so that expression control sequences effectively control expression of a coding sequence of interest.

As used herein, “transformed” and “transfected” encompass the introduction of a nucleic acid into a cell by a number of techniques known in the art.

“Plasmids” are designated by a lower case “p” preceded and/or followed by capital letters and/or numbers.

As used herein the term “heterologous” means from another host. The other host can be the same or different species.

The term “cell” refers to a membrane-bound biological unit capable of replication or division.

The term “construct” refers to a recombinant genetic molecule including one or more isolated polynucleotide sequences.

Genetic constructs used for transgene expression in a host organism comprise in the 5′-3′ direction, a promoter sequence; a nucleic acid sequence encoding the desired transgene product; and a termination sequence. The open reading frame may be orientated in either a sense or anti-sense direction. The construct may also comprise selectable marker gene(s) and other regulatory elements for expression.

The term “plant” is used in it broadest sense. It includes, but is not limited to, any species of woody, ornamental or decorative, crop or cereal, fruit or vegetable plant, and photosynthetic green algae (e.g., Chlamydomonas reinhardtii). It also refers to a plurality of plant cells that are largely differentiated into a structure that is present at any stage of a plant's development. Such structures include, but are not limited to, a fruit, shoot, stem, leaf, flower petal, etc. The term “plant tissue” includes differentiated and undifferentiated tissues of plants including those present in roots, shoots, leaves, pollen, seeds and tumors, as well as cells in culture (e.g., single cells, protoplasts, embryos, callus, etc.). Plant tissue may be in planta, in organ culture, tissue culture, or cell culture. The term “plant part” as used herein refers to a plant structure, a plant organ, or a plant tissue.

A non-naturally occurring plant refers to a plant that does not occur in nature without human intervention. Non-naturally occurring plants include transgenic plants and plants produced by non-transgenic means such as plant breeding.

The term “plant cell” refers to a structural and physiological unit of a plant, comprising a protoplast and a cell wall. The plant cell may be in form of an isolated single cell or a cultured cell, or as a part of higher organized unit such as, for example, a plant tissue, a plant organ, or a whole plant.

The term “plant cell culture” refers to cultures of plant units such as, for example, protoplasts, cell culture cells, cells in plant tissues, pollen, pollen tubes, ovules, embryo sacs, zygotes and embryos at various stages of development.

The term “plant material” refers to leaves, stems, roots, flowers or flower parts, fruits, pollen, egg cells, zygotes, seeds, cuttings, cell or tissue cultures, or any other part or product of a plant.

A “plant organ” refers to a distinct and visibly structured and differentiated part of a plant such as a root, stem, leaf, flower bud, or embryo.

“Plant tissue” refers to a group of plant cells organized into a structural and functional unit. Any tissue of a plant, whether in a plant or in culture, is included. This term includes, but is not limited to, whole plants, plant organs, plant seeds, tissue culture and any groups of plant cells organized into structural and/or functional units. The use of this term in conjunction with, or in the absence of, any specific type of plant tissue as listed above or otherwise embraced by this definition is not intended to be exclusive of any other type of plant tissue.

“Seed germination” refers to growth of an embryonic plant contained within a seed resulting in the formation and emergence of a seedling.

“Cotyledon” refers to the embryonic first leaves of a seedling.

“Early plantlet development” refers to growth of the cotyledon containing seedling to form a plantlet.

II. Transgenic Plants

Transgenic plants have been developed that produce increased levels of biopolymers such as polyhydroxyalkanoates (PHAs) in seeds. Methods and constructs for engineering plants for seed specific production of PHA, in particular PHB, are described. One embodiment provides transgenic plants for the direct, large scale production of PHAs in crop plants or in energy crops where a plant by-product, such as oil, can be used for production of energy. Proof of concept studies for polyhydroxybutyrate (PHB) synthesis in canola (Valentin et al., Int. J. Biol. Macromol., 1999, 25, 303-306; Houmiel et al., Planta, 1999, 209, 547-550; Slater et al., Nat. Biotechnol., 1999, 17, 1011-1016.) has been reported. There have been instances where high level PHB production in plastids of plants has led to decreases in total plant growth (Bohmert et al., Molecular Biology and Biotechnology of Plant Organelles, 2004, 559-585; Bohmert et al., Planta, 2000, 211, 841-845) for unidentified reasons. There have been several studies that have attempted to alleviate this problem by inducible expression of enzymes (Bohmert et al., Plant Physiol., 2002, 128, 1282-1290; Lössl et al., Plant Cell Physiol, 2005, 46, 1462-1471; Kourtz et al., Transgenic Res, 2007, 16, 759-769).

Transgenic oilseeds comprising at least about 8% dry weight PHA are provided. One embodiment provides transgenic oilseeds having at least 10% PHA dry weight and which are impaired in germination and plant survival. In other embodiments we provide transgenic oilseeds with high levels of PHA, greater than 8% of the weight of the seed and with improved seed germination and survival producing fertile plants. In this case at least about 5%, 10%, 15%, 20%, 50%, 75% or 100% of the transgenic oilseeds have the ability to germinate and survive.

A. Genetic Constructs for Transformation

Suitable genetic constructs include expression cassettes for enzymes for production of polyhydroxyalkanoates, in particular from the polyhydroxybutyrate biosynthetic pathway. In one embodiment, the construct contains operatively linked in the 5′ to 3′ direction, a seed specific promoter that directs transcription of a nucleic acid sequence in the nucleus; a nucleic acid sequence encoding one of the PHB biosynthetic enzymes; and a 3′ polyadenylation signal that increases levels of expression of transgenes. In one embodiment, enzymes for formation of polymer precursors are targeted to the plastid using appropriate plastid-targeting signals. In another embodiment, a cassette containing DNA sequences homologous to a portion of one of the transgenes and designed to promote RNA interference (RNAi) is included. In an alternative embodiment, this cassette for RNAi contains an intron between an inverted repeat. In another embodiment, a cassette with homology to one of the PHB pathway genes is designed to produce antisense RNA thus attenuating the level of translation into protein. In still another embodiment, the PHA pathway is expressed directly from the plastid genome using appropriate plastidial promoters and regulatory sequences.

In one embodiment, the construct contains operatively linked in the 5′ to 3′ direction, a promoter that directs transcription of a nucleic acid sequence in the nucleus; a nucleic acid sequence encoding genes for PHA degradation to enable seed germination; and a 3′ polyadenylation signal that increases levels of expression of transgenes. In one embodiment, enzymes for degradation of polymer are targeted to the plastid using appropriate plastid-targeting signals. In another embodiment, enzymes for polymer degradation include a depolymerase and/or dehydrogenase.

In one embodiment, the construct contains operatively linked in the 5′ to 3′ direction, a promoter that directs transcription of a nucleic acid sequence in the nucleus; a nucleic acid sequence encoding a gene to capable of increasing photosynthesis in a plant; and a 3′ polyadenylation signal that increases levels of expression of transgenes. In one embodiment, genes to increase photosynthesis include enzymes capable of increasing carbon flow through the Calvin Cycle. In one embodiment, enzymes for increasing photosynthesis are targeted to the plastid using appropriate plastid-targeting signals.

DNA constructs useful in the methods described herein include transformation vectors capable of introducing transgenes into plants. As used herein, “transgenic” refers to an organism in which a nucleic acid fragment containing a heterologous nucleotide sequence has been introduced. The transgenes in the transgenic organism are preferably stable and inheritable. The heterologous nucleic acid fragment may or may not be integrated into the host genome.

Several plant transformation vector options are available, including those described in “Gene Transfer to Plants” (Potrykus, et al., eds.) Springer-Verlag Berlin Heidelberg New York (1995); “Transgenic Plants: A Production System for Industrial and Pharmaceutical Proteins” (Owen, et al., eds.) John Wiley & Sons Ltd. England (1996); and “Methods in Plant Molecular Biology: A Laboratory Course Manual” (Maliga, et al. eds.) Cold Spring Laboratory Press, New York (1995). Plant transformation vectors generally include one or more coding sequences of interest under the transcriptional control of 5′ and 3′ regulatory sequences, including a promoter, a transcription termination and/or polyadenylation signal, and a selectable or screenable marker gene. For the expression of two or more polypeptides from a single transcript, additional RNA processing signals and ribozyme sequences can be engineered into the construct (U.S. Pat. No. 5,519,164). This approach has the advantage of locating multiple transgenes in a single locus, which is advantageous in subsequent plant breeding efforts.

Engineered minichromosomes can also be used to express one or more genes in plant cells. Cloned telomeric repeats introduced into cells may truncate the distal portion of a chromosome by the formation of a new telomere at the integration site. Using this method, a vector for gene transfer can be prepared by trimming off the arms of a natural plant chromosome and adding an insertion site for large inserts (Yu et al., Proc Natl Acad Sci USA, 2006, 103, 17331-6; Yu et al., Proc Natl Acad Sci USA, 2007, 104, 8924-9). The utility of engineered minichromosome platforms has been shown using Cre/lox and FRT/FLP site-specific recombination systems on a maize minichromosome where the ability to undergo recombination was demonstrated (Yu et al., Proc Natl Acad Sci USA, 2006, 103, 17331-6; Yu et al., Proc Natl Acad Sci USA, 2007, 104, 8924-9). Such technologies could be applied to minichromosomes, for example, to add genes to an engineered plant. Site specific recombination systems have also been demonstrated to be valuable tools for marker gene removal (Kerbach, S. et al., Theor Appl Genet, 2005, 111, 1608-1616), gene targeting (Chawla, R. et al., Plant Biotechnol J, 2006, 4, 209-218; Choi, S. et al., Nucleic Acids Res, 2000, 28, E19; Srivastava, V, & Ow, D W, Plant Mol Biol, 2001, 46, 561-566; Lyznik, L A, et al., Nucleic Acids Res, 1993, 21, 969-975), and gene conversion (Djukanovic, V, et al., Plant Biotechnol J, 2006, 4, 345-357).

An alternative approach to chromosome engineering in plants involves in vivo assembly of autonomous plant minichromosomes (Carlson et al., PLoS Genet, 2007, 3, 1965-74). Plant cells can be transformed with centromeric sequences and screened for plants that have assembled autonomous chromosomes de novo. Useful constructs combine a selectable marker gene with genomic DNA fragments containing centromeric satellite and retroelement sequences and/or other repeats.

Another approach is Engineered Trait Loci (“ETL”) technology (U.S. Pat. No. 6,077,697 to Hadlaczky et al.; US Patent Application 2006/0143732). This system targets DNA to a heterochromatic region of plant chromosomes, such as the pericentric heterochromatin, in the short arm of acrocentric chromosomes. Targeting sequences may include ribosomal DNA (rDNA) or lambda phage DNA. The perieentric rDNA region supports stable insertion, low recombination, and high levels of gene expression. This technology is also useful for stacking of multiple traits in a plant (US Patent Application 2006/0246586, 2010/0186117 and PCT WO 2010/037209).

Zinc-finger nucleases (ZFNs) are also useful in that they allow double strand DNA cleavage at specific sites in plant chromosomes such that targeted gene insertion or deletion can be performed (Shukla et al., Nature, 2009; Townsend et al., Nature, 2009).

For direct expression of transgenes from the plastid genome, a vector to transform the plant plastid chromosome by homologous recombination (as described in U.S. Pat. No. 5,545,818 to McBride et al.) is used in which case it is possible to take advantage of the prokaryotic nature of the plastid genome and insert a number of transgenes as an operon. WO 2010/061186 describes an alternative method for introducing genes into the plastid chromosome using an adapted endogenous cellular process for the transfer of RNAs from the cytoplasm to the plastid where they are incorporated by homologous recombination.

A transgene may be constructed to encode a multifunctional enzyme through gene fusion techniques in which the coding sequences of different genes are fused with or without linker sequences to obtain a single gene encoding a single protein with the activities of the individual genes. Transgenes encoding a bifunctional protein containing thiolase and reductase activities (Kourtz, L., K. et al. (2005), Plant Biotechnol. 3: 435-447) and a trifunctional protein having each of the three enzyme activities required for PHB expression in plants (Mullaney and Rehm (2010), Journal of Biotechnology 147: 31-36) have been described. Such synthetic fusion gene/enzyme combinations can be further optimized using molecular evolution technologies.

A transgene may be constructed to encode a series of enzyme activities separated by intein sequences such that on expression, two or more enzyme activities are expressed from a single promoter as described by Snell in U.S. Pat. No. 7,026,526 to Metabolix, Inc.

1. Genes involved in Polyhydroxyalkanoate Synthesis

In a preferred embodiment, the products of the transgenes are enzymes and other factors required for production of a biopolymer, such as a polyhydroxyalkanoate (PHA).

For PHA production, transgenes encode enzymes such as beta-ketothiolase, acetoacetyl-CoA reductase, PHB (“short chain”) synthase, PHA (“long chain”) synthase, threonine dehydratase, dehydratases such as 3-OH acyl ACP, isomerases such as A 3-cis, A 2-trans isomerase, propionyl-CoA synthetase, hydroxyacyl-CoA synthetase, hydroxyacyl-CoA transferase, R-3-hydroxyacyl-ACP:CoA transferase, thioesterase, fatty acid synthesis enzymes and fatty acid beta-oxidation enzymes. Useful genes are well known in the art, and are disclosed for example by Snell and Peoples Metab. Eng. 4: 29-40 (2002); Bohmert et. al in Molecular Biology and Biotechnology of Plant Organelles. H. Daniell, C. D. Chase Eds., Kluwer Academic Publishers, Netherlands, 2004, pp. 559-585; (Suriyamongkol et al., Biotechnol Adv, 2007, 25, 148-175; van Beilen et al., The Plant Journal, 2008, 54, 684-701).

PHA Svnthases

Examples of PHA synthases include a synthase with medium chain length substrate specificity, such as phaC1 from Pseudomonas oleovorans (WO 91/000917; Huisman, et al. J. Biol. Chem. 266, 2191-2198 (1991)) or Pseudomonas aeruginosa (Timm, A. & Steinbuchel, A. Eur. J. Biochem. 209: 15-30 (1992)), the synthase from Alcaligenes eutrophus with short chain length specificity (Peoples, O. P. & Sinskey, A. J. J. Biol. Chem. 264:15298-15303 (1989)), or a two subunit synthase such as the synthase from Thiocapsa pfennigii encoded by phaE and phaC (U.S. Pat. No. 6,011,144). Other useful PHA synthase genes have been isolated from, for example, Alcaligenes latus (Accession ALU47026), Burkholderia sp. (Accession AF153086), Aeromonas caviae (Fukui & Doi, J. Bacteriol. 179: 4821-30 (1997)), Acinetobacter sp.

strain RA3849 (Accession L37761), Rhodospirillum rubrum (U.S. Pat. No. 5,849,894), Rhodococcus ruber (Pieper & Steinbuechel, FEMS Microbiol. Lett. 96(1): 73-80 (1992)), Nocardia corallina (Hall et. al., Can. J. Microbiol. 44: 687-91 (1998)), Arthrospira sp. PCC 8005 (Accessions ZP_—07166315 and ZP_—07166316), Cyanothece sp. PCC 7425 (Accessions ACL46371 and ACL46370) and Synechocystis sp. PCC6803 (Accession BAA17430; Hein et al. (1998), Archives of Microbiology 170: 162-170).

PHA synthases with broad substrate specificity useful for producing copolymers of 3-hydroxybutyrate and longer chain length (from 6 to 14 carbon atoms) hydroxyacids have also been isolated from Pseudomonas sp. A33 (Appl. Microbiol. Biotechnol. 42: 901-909 (1995)) and Pseudomonas sp. 61-3 (Accession AB014757; Kato, et al. Appl. Microbiol. Biotechnol. 45: 363-370 (1996)).

A range of PHA synthase genes and genes encoding additional metabolic steps useful in PHA biosynthesis are described by Madison and Huisman. Microbiology and Molecular biology Reviews 63:21-53 (1999)) and Suriyamongkol et al. (Suriyamongkol et al., Biotechnol Adv, 2007, 25, 148-175).

Hydratase and Dehydrogenase

An alpha subunit of beta-oxidation multienzyme complex pertains to a multifunctional enzyme that minimally possesses hydratase and dehydrogenase activities. The subunit may also possess epimerase and Δ3-cis, Δ2-trans isomerase activities. Examples of alpha subunits of the beta-oxidation multienzyme complex are FadB from E. coli (DiRusso, C. C. J. Bacterial. 1990, 172, 6459-6468), FaoA from Pseudomonas fragi (Sato, S., Hayashi, et al. J. Biochem. 1992, 111, 8-15), and the E. coli open reading frame f714 that contains homology to multifunctional α subunits of the β-oxidationcomplex (Genbank Accession #1788682). A β subunit of the β-oxidationcomplex refers to a polypeptide capable of forming a multifunctional enzyme complex with its partner α subunit. The β subunit possesses thiolase activity. Examples of β subunits are FadA from E. coli (DiRusso, C. C. J. Bacterial. 172: 6459-6468 (1990)), FaoB from Pseudomonas fragi (Sato, S., Hayashi, M., Imamura, S., Ozeki, Y., Kawaguchi, A. J. Biochem. 111: 8-15 (1992)), and the E. coli open reading frame f436 that contains homology to α subunits of the β-oxidation complex (Genbank Accession #AE000322; gene b2342).

Reductases

The transgene can encode a reductase. A reductase refers to an enzyme that can reduce β-ketoacyl CoAs to R-3-OH-acyl CoAs, such as the NADH dependent reductase from Chromatium vinosum (Liebergesell, M., & Steinbuchel, A. Eur. J. Biochem. 209: 135-150 (1992)), the NADPH dependent reductase from Alcaligenes eutrophus (Accession J04987, Peoples, O. P. & Sinskey, A. J. J. Biol. Chem. 264: 15293-15297 (1989))), the NADPH reductase from Zoogloea ramigera (Accession P23238; Peoples, O. P. & Sinskey, A. J. Molecular Microbiology 3: 349-357 (1989)) or the NADPH reductase from Bacillus megaterium (U.S. Pat. No. 6,835,820), Alcaligenes latus (Accession ALU47026), Rhizobium meliloti (Accession RMU17226), Paracoccus denitrificans (Accession D49362), Burkholderia sp. (Accession AF153086), Pseudomonas sp. strain 61-3 (Accession AB014757), Acinetobacter sp. strain RA3849 (Accession L37761), P. denitrificans, (Accession P50204), and Synechocystis sp. Strain PCC6803 (Taroncher-Oldenburg et al., (2000), Appl. Environ. Microbiol. 66: 4440-4448).

Thiolases

The transgene can encode a thiolase. A beta-ketothiolase refers to an enzyme that can catalyze the conversion of acetyl CoA and an acyl CoA to a β-ketoacyl CoA, a reaction that is reversible. An example of such thiolases are PhaA from Alcaligenes eutropus (Accession J04987, Peoples, O. P. & Sinskey, A. J. J. Biol. Chem. 264: 15293-15297 (1989)), BktB from Alcaligenes eutrophus (Slater et al. J Bacteriol. 180(8):1979-87 (1998)), and thiolases from the following Rhizobium meliloti (Accession RMU17226), Z. ramigera (Accession P07097), Paracoccus denitrificans (Accession D49362), Burkholderia sp. (Accession AF153086), Alcaligenes latus (Accession ALU47026), Allochromatium vinosum (Accession P45369), Thiocystis violacea (Accession P45363); Pseudomonas sp. strain 61-3 (Accession AB014757), Acinetobacter sp. strain RA3849 (Accession L37761) and Synechocystis sp. Strain PCC6803 (Taroncher-Oldenburg et al., (2000), Appl. Environ. Microbiol. 66: 4440-4448).

Oxidases

An acyl CoA oxidase refers to an enzyme capable of converting saturated acyl CoAs to Δ2 unsaturated acyl CoAs. Examples of acyl CoA oxidases are PDX1 from Saccharomyces cerevisiae (Dmochowska, et al. Gene, 1990, 88, 247-252) and ACX1 from Arabidopsis thaliana (Genbank Accession #AF057044).

Catalases

The transgene can also encode a catalase. A catalase refers to an enzyme capable of converting hydrogen peroxide to hydrogen and oxygen. Examples of catalases are KatB from Pseudomonas aeruginosa (Brown, et al. J. Bacterial. 177: 6536-6544 (1995)) and KatG from E. coli (Triggs-Raine, B. L. & Loewen, P. C. Gene 52: 121-128 (1987)).

2. siRNA

The disclosed constructs and transgenic plants may also produce small inhibitory RNA molecules (siRNA) that can be single stranded or double stranded RNA molecules generally less than 200 nucleotides in length. Such molecules are generally less than 100 nucleotides and usually vary from 10 to 100 nucleotides in length. In a preferred format, siRNA molecules have 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29 or 30 nucleotides and bind to and inhibit translation of mRNA encoding one or more of the genes involved in production of polyhydroxyalkanoates discussed above. The term “siRNA” means a small interfering RNA that is a short-length, preferably double-stranded RNA that is not toxic. Generally, there is no particular limitation in the length of siRNA as long as it does not show toxicity. “siRNAs” can be, for example, 15 to 49 bp, preferably 15 to 35 bp, and more preferably 21 to 30 bp long. Alternatively, the double-stranded RNA portion of a final transcription product of siRNA to be expressed can be, for example, 15 to 49 bp, preferably 15 to 35 bp, and more preferably 21 to 30 bp long. The double-stranded RNA portions of siRNAs in which two RNA strands pair up are not limited to the completely paired ones, and may contain nonpairing portions due to mismatch (the corresponding nucleotides are not complementary), bulge (lacking in the corresponding complementary nucleotide on one strand), and the like. Nonpairing portions can be contained to the extent that they do not interfere with siRNA formation. The “bulge” used herein preferably comprise 1 to 2 nonpairing nucleotides, and the double-stranded RNA region of siRNAs in which two RNA strands pair up contains preferably 1 to 7, more preferably 1 to 5 bulges. In addition, the “mismatch” used herein is contained in the double-stranded RNA region of siRNAs in which two RNA strands pair up, preferably 1 to 7, more preferably 1 to 5, in number. In a preferable mismatch, one of the nucleotides is guanine, and the other is uracil. Such a mismatch is due to a mutation from C to T, G to A, or mixtures thereof in DNA coding for sense RNA, but not particularly limited to them. Furthermore, the double-stranded RNA region of siRNAs in which two RNA strands pair up may contain both bulge and mismatched, which sum up to, preferably 1 to 7, more preferably 1 to 5 in number. The terminal structure of siRNA may be either blunt or cohesive (overhanging) as long as siRNA can silence, reduce, or inhibit the target gene expression due to its RNAi effect. The cohesive (overhanging) end structure is not limited only to the 3′ overhang, and the 5′ overhanging structure may be included as long as it is capable of inducing the RNAi effect. In addition, the number of overhanging nucleotide is not limited to the already reported 2 or 3, but can be any numbers as long as the overhang is capable of inducing the RNAi effect. For example, the overhang consists of 1 to 8, preferably 2 to 4 nucleotides. Herein, the total length of siRNA having cohesive end structure is expressed as the sum of the length of the paired double-stranded portion and that of a pair comprising overhanging single-strands at both ends. For example, in the case of 19 bp double-stranded RNA portion with 4 nucleotide overhangs at both ends, the total length is expressed as 23 bp. Furthermore, since this overhanging sequence has low specificity to a target gene, it is not necessarily complementary (antisense) or identical (sense) to the target gene sequence. Furthermore, as long as siRNA is able to maintain its gene silencing effect on the target gene, siRNA may contain a low molecular weight RNA (which may be a natural RNA molecule such as tRNA, rRNA or viral RNA, or an artificial RNA molecule), for example, in the overhanging portion at its one end.

In addition, the terminal structure of the “siRNA” is not necessarily the cut off structure at both ends as described above, and may have a stem-loop structure in which ends of one side of double-stranded RNA are connected by a linker RNA. The length of the double-stranded RNA region (stem-loop portion) can be, for example, 15 to 49 bp, preferably 15 to 35 bp, and more preferably 21 to 30 bp long. Alternatively, the length of the double-stranded RNA region that is a final transcription product of siRNAs to be expressed is, for example, 15 to 49 bp, preferably 15 to 35 bp, and more preferably 21 to 30 bp long. Furthermore, there is no particular limitation in the length of the linker as long as it has a length so as not to hinder the pairing of the stem portion. For example, for stable pairing of the stem portion and suppression of the recombination between DNAs coding for the portion, the linker portion may have a clover-leaf tRNA structure. Even though the linker has a length that hinders pairing of the stem portion, it is possible, for example, to construct the linker portion to include introns so that the introns are excised during processing of precursor RNA into mature RNA, thereby allowing pairing of the stem portion. In the case of a stem-loop siRNA, either end (head or tail) of RNA with no loop structure may have a low molecular weight RNA. As described above, this low molecular weight RNA may be a natural RNA molecule such as tRNA, rRNA or viral RNA, or an artificial RNA molecule.

The design of the siRNA molecules can be achieved using conventional software. Because the nucleotide sequences of all of the genes involved in PHA production are known, one of skill in the art could input this sequence data into the siRNA software to design specific siRNA molecules that can be expressed by the transgenic plant to inhibit expression of one or more transgenes involved in PHA production.

3. PHB Degradation Pathway enzymes

The disclosed constructs may contain a transgene expressing a PHA depolymerase. There are two kinds of depolymerases, one that is used by micro-organisms to degrade polymer intracellularly (intracellular depolymerases, and another that is secreted from the micro-organism to degrade extracellular polymer (extracellular depolymerases). There are also depolymerases with specificity for short chain length polymers such as PHS (EC 3.1.1.75) and depolymerases with specificity for medium chain length polymers (EC 3.1.1.76). Depolymerases suitable for this invention include but are not limited to the intracellular depolymerase PhaZ3 from Cupriavidus necator (formerly known as Ralstonia eutropha) (Accession AAP74581), the intracellular depolymerase PhaZ2 from Cupriavidus necator (Accession AAP74580), the intracellular depolymerase PhaZ1 from Ralstonia eutropha (Accession AB017612) (Saegusa, H., M. Shiraki, et al., 2001, J. Bacteriol. 183: 94-100; York, G. M. et al., 2003, J. Bacteriol. 185: 3788-3794), the extracellular depolymerase from Rhodospirillum rubrum (Accession AAL30107), and the extracellular depolymerase from Ralstonia picketti (Accession J04223). The degradation of PHAs as well as references for suitable depolymerases are reviewed in Tokiwa & Calabia (Tokiwa and Calabia, (2004), Biotechnology Letters 26: 1181-1189), Jeddrossek (Jendrossek, D. (2009), J. Bacteriol. 191(10): 3195-3202), and Jendrossek and Handrick (Jendrossek and Handrick (2002). Annu Rev Microbiol 56: 403-432) which are herein incorporated by reference in their entirety.

The disclosed constructs may also contain a transgene encoding a 3-hydroxybutyrate dehydrogenase (EC 1.1.1.30). This enzyme catalyzes the conversion of 3-hydroxybutrate to acetoacetate (FIG. 3). Suitable 3-hydroxybutrate dehydrogenases include but are not limited to the D(−)-3-hydroxybutyrate dehydrogenase (hbdh) from Pseudomonas fragi (Accession AB183516), Bordetella pertussis (Accession BX640418), Ralstonia eutropha (Accession AF145230), Pseudomonas aeruginosa (Accession AE004626), Azospirillum brasilense (Accession AF355575), Caulobacter crescentus (Accession AE005999), Brucella melitensis (Accession AE009469), and Rhodobacter (Accession AF037323).

4. Additional Enzymes to Enhance Photosynthesis and/or Carbon Flux

The disclosed constructs may also contain expression cassettes for one or more transgenes encoding enzymes capable of increasing photosynthesis, increasing carbon flow through the Calvin cycle in photosynthesis, or increasing regeneration of ribulose 1,5-bisphosphate, the acceptor molecule in the Calvin cycle that upon fixation of CO₂, is converted to two molecules of 3-phosphoglycerate.

Candidate enzymes include but are not limited to sedoheptulose 1,7-bisphosphatase (SBPase, EC 3.1.3.37), fructose 1,6-bisphosphatase (FBPase, EC 3.1.3.11), a bi-functional enzyme encoding both SBPase and FBPase activities, transketolase (EC 2.2.1.1), and aldolase (EC 4.1.2.13). SBPase, transketolase, and aldolase activities have been shown to have an impact on the control of carbon fixed by the Calvin cycle (Raines, 2003, Photosynthesis Research, 75, 1-10) which could be attributed to an increase in ribulose 1,5-bisphosphate regenerative capacity.

Bifunctional enzymes that contain both FBPase and SBPase activities have been reported from for example Ralstonia eutropha H16 (Accession number AAA69974), Synechococcus elongatus PCC 7942 (Accession numbers D83512 and CP000100), Synechococcus sp. WH 7805 (Accession number ZP_—01124026), Butyrivibrio crossotus DSM 2876 (Accession number EFF67670), Rothia mucilaginosa DY-18 (Accession number YP_—003363264), Thiobacillus denitrificans ATCC 25259 (Accession number AAZ98530), Methylacidiphilum infernorum V4 (Accession number ACD83413), Nitrosomonas europaea ATCC 19718 (Accession number CAD84432), Vibrio vulnificus CMCP6 (Accession number AA009802), and Methanohalophilus mahii DSM 5219 (Accession number YP_—003542799).

The FBPase/SBPase gene from Synechococcus elongatus PCC 7942 has previously been expressed in tobacco and enhanced both photosynthesis and plant growth (Miyagawa, 2001, Nat. Biotechnol., 19, 965-969). Expression of an Arabidopsis SBPase cDNA in tobacco also has resulted in greater biomass and increased photosynthetic capacity (Raines, 2003, Photosynthesis Research, 75, 1-10; Lefebvre et al., 2005, Plant Physiol. 138, 451-460).

Enzymes possessing SBPase activity that could be used to increase the flow of carbon within the Calvin cycle include for example the sedoheptulose-1,7-bisphosphatase from Zea mays (Accession NP_—001148402), the sedoheptulose-1,7-bisphosphatase from Arabidopsis thaliana (Accession AAB33001), or the sedoheptulose-1,7-bisphosphatase from Triticum aestivum (Accession P46285).

Enzymes possessing FBPase that could be used to increase the flow of carbon within the Calvin cycle include for example the protein encoded by the fbpI gene from Synechococcus elongatus PCC 6301 (Accession number AP008231.1), a D-fructose 1,6-bisphosphatase from Synechococcus elongatus PCC 7942 (Accession number CP000100), the gene encoding fructose-1,6-bisphosphatase from Zea mays (Accession NP_—001147459), the gene encoding fructose-1,6-bisphosphatase from Saccharum hybrid cultivar 1-165-7052 (Accession CAA61409) and the fructose-1,6-bisphosphatase from Pisum sativum (Accession AAD10213).

Enzymes possessing transketolase activity that could be used to increase the flow of carbon within the Calvin cycle include for example the transketolase from Cyanobacterium UCYN-A (Accession YP_—003421778), the transketolase from Spinacia oleracea (Accession AAD 10219), the transketolase from Rhodbacter capsulatus SB 1003 (Accession AAC32307), and the transketolase from Esherichia coli K-12 MG1655 (Accession AAA69102).

Enzymes possessing adolase activity that could be used to increase the flow of carbon within the Calvin cycle include for example the aldolase from Synechococcus sp. CC9902 (ACCESSION YP_—378043) the ketose-bisphosphate aldolase from Crocosphaera watsonii WH 8501 (ACCESSION EAM50168), the fructose-bisphosphate aldolase 1 from Rhodobacter sphaeroides (Accession number P27995), and the fructose-1,6-/sedoheptulose-1,7-bisphosphate aldolase from Nitrobacter vulgaris (Accession P37102).

Co-expression of RUBISCO with one or more of the above enzymes could further increase the rate of photosynthesis.

5. Promoters

Plant promoters can be selected to control the expression of the transgene in different plant tissues or organelles for all of which methods are known to those skilled in the art (Gasser & Fraley, Science 244:1293-99 (1989)). In one embodiment, promoters are selected from those of eukaryotic or synthetic origin that are known to yield high levels of expression in plant and algae cytosol. In another embodiment, promoters are selected from those of plant or prokaryotic origin that are known to yield high expression in plastids. In certain embodiments the promoters are inducible. Inducible plant promoters are known in the art.

Suitable constitutive promoters for nuclear-encoded expression include, for example, the core promoter of the Rsyn7 promoter and other constitutive promoters disclosed in U.S. Pat. No. 6,072,050; the core CAMV 35S promoter, (Odell et al. (1985) Nature 313:810-812); rice actin (McElroy et al. (1990) Plant Cell 2:163471); ubiquitin (Christensen et al. (1989) Plant Mol. Biol. 12:619-632 and Christensen et al. (1992) Plant Mot Biol. 18:675-689); pEMU (Last et al. (1991) Theor. Appl. Genet. 81:581-588); MAS (Velten et al. (1984) EMBO J. 3:2723-2730); and ALS promoter (U.S. Pat. No. 5,659,026). Other constitutive promoters include, for example, U.S. Pat. Nos. 5,608,149; 5,608,144; 5,604,121; 5,569,597; 5,466,785; 5,399,680; 5,268,463; 5,608,142.

“Tissue-preferred” promoters can be used to target a gene expression within a particular tissue such as seed, leaf or root tissue. Tissue-preferred promoters include Yamamoto et al. (1997) Plant J. 12(2)255-265; Kawamata et al. (1997) Plant Cell Physiol. 38(7):792-803; Hansen et al (1997) Mol. Gen. Genet. 254(3):337-343; Russell et al. (1997) Transgenic Res. 6(2):157-168; Rinehart et al. (1996) Plant Physiol. 112(3):1331-1341; Van Camp et al (1996) Plant Physiol. 112(2):525-535; Canevascini et al. (1996) Plant Physiol. 112(2):513-524; Yamamoto et al. (1994) Plant Cell Physiol. 35(5):773-778; Lam (1994) Results Probl. Cell Differ. 20:181-196; Orozco et al. (1993) Plant Mol. Biol. 23(6):1129-1138; Matsuoka et al. (1993) Proc Natl. Acad. Sci. USA 90(20):9586-9590; and Guevara-Garcia et al. (1993) Plant J. 4(3):495-505.

“Seed-preferred” promoters include both “seed-specific” promoters (those promoters active during seed development such as promoters of seed storage proteins) as well as “seed-germinating” promoters (those promoters active during seed germination). See Thompson et al. (1989) BioEssays 10:108. Such seed-preferred promoters include, but are not limited to, Cim1 (cytokinin-induced message); cZ19B1 (maize 19 kDa zein); milps (myo-inositol-1-phosphate synthase); and ce1A (cellulose synthase). Gama-zein is a preferred endosperm-specific promoter. Glob-1 is a preferred embryo-specific promoter. For dicots, seed-specific promoters include, but are not limited to, bean β-phaseolin, napin β-conglycinin, soybean lectin, cruciferin, oleosin, the Lesquerella hydroxylase promoter, and the like. For monocots, seed-specific promoters include, but are not limited to, maize 15 kDa zein, 22 kDa zein, 27 kDa zein, g-zein, waxy, shrunken 1, shrunken 2, globulin 1, etc. Additional seed specific promoters useful for practicing this invention are described in the Examples disclosed herein.

Leaf-specific promoters are known in the art. See, for example, Yamamoto et al. (1997) Plant J. 12(2):255-265; Kwon et al. (1994) Plant Physiol. 105:357-67; Yamamoto et al. (1994) Plant Cell Physiol. 35(5):773-778; Gotor et al. (1993) Plant J. 3:509-18; Orozco et al. (1993) Plant Mol. Biol. 23(6):1129-1138; and Matsuoka et al. (1993) Proc. Natl. Acad. Sci. USA 90(20):9586-9590.

Root-preferred promoters are known and may be selected from the many available from the literature or isolated de novo from various compatible species. See, for example, Hire et al. (1992) Plant Mol. Biol. 20(2): 207-218 (soybean root-specific glutamine synthetase gene); Keller and Baumgartner (1991) Plant Cell 3(10):1051-1061 (root-specific control element in the GRP 1.8 gene of French bean); Sanger et al. (1990) Plant Mol. Biol. 14(3):433-443 (root-specific promoter of the mannopine synthase (MAS) gene of Agrobacterium tumefaciens); and Miao et al. (1991) Plant Cell 3(1):1 1′-22 (full-length cDNA clone encoding cytosolic glutamine synthetase (GS), which is expressed in roots and root nodules of soybean). See also U.S. Pat. Nos. 5,837,876; 5,750,386; 5,633,363; 5,459,252; 5,401,836; 5,110,732; and 5,023,179.

Plastid specific promoters include the PrbcL promoter [Allison L. A. et al., EMBO 15: 2802-2809 (1996); Shiina T. et al., Plant Cell 10: 1713-1722 (1998)]; the PpsbA promoter [Agrawal O K, et al., Nucleic Acids Research 29: 1835-1843 (2001)]; the Prrn 16 promoter [Svab Z & Maliga P., Proc. Natl. Acad. Sci. USA 90: 913-917 (1993), Allison L A et al., EMBO 15: 2802-2809 (1996)]; the PaccD promoter (WO97/06250; Hajdukiewicz P T J et al., EMBO J. 16: 4041-4048 (1997)).

Chemical-regulated promoters can be used to modulate the expression of a gene in a plant through the application of an exogenous chemical regulator. Depending upon the objective, the promoter may be a chemical-inducible promoter, where application of the chemical induces gene expression, or a chemical-repressible promoter, where application of the chemical represses gene expression. Chemical-inducible promoters are known in the art and include, but are not limited to, the maize 1n2-2 promoter, which is activated by benzenesulfonamide herbicide safeners, the maize GST promoter, which is activated by hydrophobic electrophilic compounds that are used as pre-emergent herbicides, and the tobacco PR-1a promoter, which is activated by salicylic acid. Other chemical-regulated promoters of interest include steroid-responsive promoters (see, for example, the glucocorticoid-inducible promoter in Schena et al. Proc. Natl. Acad. Sci. USA 88:10421-10425 (1991) and McNellis et al. Plant J. 14(2):247-257 (1998)) and tetracycline-inducible and tetracycline-repressible promoters (see, for example, Gatz et al. Mol. Gen. Genet. 227:229-237 (1991), and U.S. Pat. Nos. 5,814,618 and 5,789,156), herein incorporated by reference in their entirety.

In one embodiment, coordinated expression of the three transgenes, phaA, phaB, and phaC, necessary for conversion of acetyl-CoA to PHB is controlled by a seed specific promoter, such as the soybean oleosin promoter (Rowley et al., Biochim Biophys Acta, 1997, 1345, 1-4) or the promoter from the lesquerlla hydroxylase gene (U.S. Pat. No. 6,437,220 B1). In another embodiment, coordinated expression of the three transgenes, phaA, phaB, and phaC, necessary for conversion of acetyl-CoA to PHB is controlled by a promoter active primarily in the biomass plant, such as the maize chlorophyll A/B binding protein promoter (Sullivan et al., Mol. Gen. Genet., 1989, 215, 431-40). It has been previously shown that plants transformed with multi-gene constructs produced higher levels of polymer than plants obtained from crossing single transgene lines (Valentin et al., Int. J. Biol. Macromol., 1999, 25, 303-306; Bohmert et al., Planta, 2000, 211, 841-845).

In one embodiment, the final molecular weight of the polymer produced is controlled by the choice of promoter for expression of the PHA synthase gene. As described in U.S. Pat. No. 5,811,272, high PHA synthase activity will lower polymer molecular weight and low PHA synthase activity will increase polymer molecular weight. In another embodiment, a strong promoter is used for expression of the genes encoding plastid-targeted monomer producing enzymes while a weaker promoter is used to control expression of synthase.

6. Transcription Termination Sequences

At the extreme 3′ end of the transcript of the transgene, a polyadenylation signal can be engineered. A polyadenylation signal refers to any sequence that can result in polyadenylation of the mRNA in the nucleus prior to export of the mRNA to the cytosol, such as the 3′ region of nopaline synthase (Bevan, M., Barnes, W. M., Chilton, M. D. Nucleic Acids Res. 1983, 11, 369-385).

7. Selectable Markers

Genetic constructs may encode a selectable marker to enable selection of plastid transformation events. There are many methods that have been described for the selection of transformed plants [for review see (Miki et al., Journal of Biotechnology, 2004, 107, 193-232) and references incorporated within]. Selectable marker genes that have been used extensively in plants include the neomycin phosphotransferase gene nptII (U.S. Pat. Nos. 5,034,322, U.S. Pat. No. 5,530,196), hygromycin resistance gene (U.S. Pat. No. 5,668,298), the bar gene encoding resistance to phosphinothricin (U.S. Pat. No. 5,276,268), the expression of aminoglycoside 3″-adenyltransferase (aadA) to confer spectinomycin resistance (U.S. Pat. No. 5,073,675), the use of inhibition resistant 5-enolpyruvyl-3-phosphoshikimate synthetase (U.S. Pat. No. 4,535,060) and methods for producing glyphosate tolerant plants (U.S. Pat. No. 5,463,175; U.S. Pat. No. 7,045,684). Methods of plant selection that do not use antibiotics or herbicides as a selective agent have been previously described and include expression of glucosamine-6-phosphate deaminase to inactive glucosamine in plant selection medium (U.S. Pat. No. 6,444,878) and a positive/negative system that utilizes D-amino acids (Erikson et al., Nat Biotechnol, 2004, 22, 455-8). European Patent Publication No. EP 0 530 129 A1 describes a positive selection system which enables the transformed plants to outgrow the non-transformed lines by expressing a transgene encoding an enzyme that activates an inactive compound added to the growth media. U.S. Pat. No. 5,767,378 describes the use of mannose or xylose for the positive selection of transgenic plants. Methods for positive selection using sorbitol dehydrogenase to convert sorbitol to fructose for plant growth have also been described (WO 2010/102293). Screenable marker genes include the beta-glucuronidase gene (Jefferson et al., 1987, EMBO J. 6: 3901-3907; U.S. Pat. No. 5,268,463) and native or modified green fluorescent protein gene (Cubitt et al., 1995, Trends Biochem. Sci. 20: 448-455; Pan et al., 1996, Plant Physiol. 112: 893-900).

Transformation events can also be selected through visualization of fluorescent proteins such as the fluorescent proteins from the nonbioluminescent Anthozoa species which include DsRed, a red fluorescent protein from the Discosoma genus of coral (Matz et al. (1999), Nat Biotechnol 17: 969-73). An improved version of the DsRed protein has been developed (Bevis and Glick (2002), Nat Biotech 20: 83-87) for reducing aggregation of the protein. Visual selection can also be performed with the yellow fluorescent proteins (YFP) including the variant with accelerated maturation of the signal (Nagai, T. et al. (2002), Nat Biotech 20: 87-90), the blue fluorescent protein, the cyan fluorescent protein, and the green fluorescent protein (Sheen et al. (1995), Plant J 8: 777-84; Davis and Vierstra (1998), Plant Molecular Biology 36: 521-528). A summary of fluorescent proteins can be found in Tzfira et al. (Tzfira et al. (2005), Plant Molecular Biology 57: 503-516) and Verkhusha and Lukyanov (Verkhusha, V. V. and K. A. Lukyanov (2004), Nat Biotech 22: 289-296) whose references are incorporated in entirety. Improved versions of many of the fluorescent proteins have been made for various applications. Use of the improved versions of these proteins or the use of combinations of these proteins for selection of transformants will be obvious to those skilled in the art. It is also practical to simply analyze progeny from transformation events for the presence of the PHB thereby avoiding the use of any selectable marker.

For plastid transformation constructs, a preferred selectable marker is the spectinomycin-resistant allele of the plastid 16S ribosomal RNA gene (Staub J M, Maliga P, Plant Cell 4: 39-45 (1992); Svab Z, Hajdukiewicz P, Maliga P, Proc. Natl. Acad. Sci. USA 87: 8526-8530 (1990)). Selectable markers that have since been successfully used in plastid transformation include the bacterial aadA gene that encodes aminoglycoside 3′-adenyltransferase (AadA) conferring spectinomycin and streptomycin resistance (Svab et al., Proc. Natl. Acad. Sci. USA, 1993, 90, 913-917), nptII that encodes aminoglycoside phosphotransferase for selection on kanamycin (Caner H, Hockenberry Tenn., Svab Z, Maliga P., Mol. Gen. Genet. 241: 49-56 (1993); Lutz K A, et al., Plant J. 37: 906-913 (2004); Lutz K A, et al., Plant Physiol. 145: 1201-1210 (2007)), aphA6, another aminoglycoside phosphotransferase (Huang F-C, et al, Mol. Genet. Genomics 268: 19-27 (2002)), and chloramphenicol acetyltransferase (Li, W., et al. (2010), Plant Mol Biol, DOI_—10.1007/s11103-010-9678-4). Another selection scheme has been reported that uses a chimeric betaine aldehyde dehydrogenase gene (BADH) capable of converting toxic betaine aldehyde to nontoxic glycine betaine. (Daniell H, et al., Curr. Genet. 39: 109-116 (2001)).

8. Plastid Targeting Signals

Plastid targeting sequences are known in the art and include the chloroplast small subunit of ribulose-1,5-bisphosphate carboxylase (Rubisco) (de Castro Silva Filho et al, Plant Mol. Biol. 30:769-780 (1996); Schnell et al. J. Biol. Chem. 266(5):3335-3342 (1991)); 5-(enolpyruvyl)shikimate-3-phosphate synthase (EPSPS) (Archer et al. J. Bioenerg. Biomemb. 22(6):789-810 (1990)); tryptophan synthase (Zhao et al. J. Biol. Chem. 270(11):6081-6087 (1995)); plastocyanin (Lawrence et al. J. Biol. Chem. 272(33):20357-20363 (1997)); chorismate synthase (Schmidt et al. J. Biol. Chem. 268(36):27447-27457 (1993)); and the light harvesting chlorophyll a/b binding protein (LHBP) (Lamppa et al. J. Biol. Chem. 263:14996-14999 (1988)). See also Von Heijne et al. Plant Mol. Biol. Rep. 9:104-126 (1991); Clark et al. J. Biol. Chem. 264:17544-17550 (1989); Della-Cioppa et al. Plant Physiol. 84:965-968 (1987); Romer et al. Biochem. Biophys. Res. Commun. 196:1414-1421 (1993); and Shah et al. Science 233:478-481 (1986). Alternative plastid targeting signals have also been described in the following: US 2008/0263728; Miras, S. et al. (2002), J Biol Chem 277(49): 47770-8; Miras, S. et al. (2007), J Biol Chem 282: 29482-29492.

B. Exemplary Host Plants

Plants transformed in accordance with the present disclosure may be monocots or dicots. The transformation of suitable agronomic plant hosts using vectors for nuclear transformation or direct plastid transformation can be accomplished with a variety of methods and plant tissues. Representative plants useful in the methods disclosed herein include the Brassica family including B. napus, B. rapa, B. carinata and B. juncea; industrial oilseeds such as Camelina sativa, Crambe, Jatropha, castor; Calendula, Cuphea, Arabidopsis thaliana; maize; soybean; cottonseed; sunflower; palm; coconut; safflower; peanut; mustards including Sinapis alba; sugarcane flax and tobacco, also are useful with the methods disclosed herein. Representative tissues for transformation using these vectors include protoplasts, cells, callus tissue, leaf discs, pollen, and meristems.

C. Methods of Plant Transformation

Transformation protocols as well as protocols for introducing nucleotide sequences into plants may vary depending on the type of plant or plant cell targeted for transformation. Suitable methods of introducing nucleotide sequences into plant cells and subsequent insertion into the plant genome include microinjection (Crossway et al. (1986) Biotechniques 4:320-334), electroporation (Riggs et al. (1986) Proc. Natl. Acad. Sci. USA 83:5602-5606), Agrobacterium-mediated transformation (Townsend et al., U.S. Pat. No. 5,563,055; Zhao et al. WO US98/01268), direct gene transfer (Paszkowski et al. (1984) EMBO J. 3:2717-2722), and ballistic particle acceleration (see, for example, Sanford et al., U.S. Pat. No. 4,945,050; Tomes et al. (1995) Plant Cell, Tissue, and Organ Culture: Fundamental Methods, ed. Gamborg and Phillips (Springer-Verlag, Berlin); and McCabe et al. Biotechnology 6:923-926 (1988)). Also see Weissinger et al. Ann. Rev. Genet. 22:421-477 (1988); Sanford et al. Particulate Science and Technology 5:27-37 (1987) (onion); Christou et al. Plant Physiol. 87:671-674 (1988) (soybean); McCabe et al. (1988) BioTechnology 6:923-926 (soybean); Finer and McMullen In Vitro Cell Dev. Biol. 27P:175-182 (1991) (soybean); Singh et al. Theor. Appl. Genet. 96:319-324 (1998)(soybean); Dafta et al. (1990) Biotechnology 8:736-740 (rice); Klein et al. Proc. Natl. Acad. Sci. USA 85:4305-4309 (1988) (maize); Klein et al. Biotechnology 6:559-563 (1988) (maize); Tomes, U.S. Pat. No. 5,240,855; Buising et al., U.S. Pat. Nos. 5,322,783 and 5,324,646; Tomes et al. (1995) in Plant Cell, Tissue, and Organ Culture Fundamental Methods, ed. Gamborg (Springer-Verlag, Berlin) (maize); Klein et al. Plant Physiol. 91:440-444 (1988) (maize); Fromm et al. Biotechnology 8:833-839 (1990) (maize); Hooykaas-Van Slogteren et al. Nature 311:763-764 (1984); Bowen et al., U.S. Pat. No. 5,736,369 (cereals); Bytebier et al. Proc. Natl. Acad. Sci. USA 84:5345-5349 (1987) (Liliaceae); De Wet et al. in The Experimental Manipulation of Ovule Tissues, ed. Chapman et al. (Longman, N.Y.), pp. 197-209 (1985) (pollen); Kaeppler et al. Plant Cell Reports 9:415-418 (1990) and Kaeppler et al. Theor. Appl. Genet. 84:560-566 (1992) (whisker-mediated transformation); D'Halluin et al. Plant Cell 4:1495-1505 (1992) (electroporation); Li et al. Plant Cell Reports 12:250-255 (1993) and Christou and Ford Annals of Botany 75:407-413 (1995) (rice); Osjoda et al. Nature Biotechnology 14:745-750 (1996) (maize via Agrobacterium tumefaciens); all of which are herein incorporated by reference in their entirety. Methods for transforming plant protoplasts are available including transformation using polyethylene glycol (PEG), electroporation, and calcium phosphate precipitation (see for example Potrykus et al., 1985, Mol. Gen. Genet., 199, 183-188; Potrykus et al., 1985, Plant Molecular Biology Reporter, 3, 117-128), Methods for plant regeneration from protoplasts have also been described [Evans et al., in Handbook of Plant Cell Culture, Vol 1, (Macmillan Publishing Co., New York, 1983); Vasil, IK in Cell Culture and Somatic Cell Genetics (Academic, Orlando, 1984)].

Methods for transformation of plastids such as chloroplasts are known in the art. See, for example, Svab et al. (1990) Proc. Natl. Acad. Sci. USA 87:8526-8530; Svab and Maliga (1993) Proc. Natl. Acad. Sci. USA 90:913-917; Svab and Maliga (1993) EMBO J. 12:601-606. The method relies on particle gun delivery of DNA containing a selectable marker and targeting of the DNA to the plastid genome through homologous recombination. Additionally, plastid transformation may be accomplished by transactivation of a silent plastid-borne transgene by tissue-preferred expression of a nuclear-encoded and plastid-directed RNA polymerase (McBride et al., Proc. Natl. Acad. Sci. USA, 1994, 91:7301-7305) or by use of an integrase, such as the phiC31 phage site-specific integrase, to target the gene insertion to a previously inserted phage attachment site (Lutz et al., Plant J, 2004, 37, 906-13). Plastid transformation vectors can be designed such that the transgenes are expressed from a promoter sequence that has been inserted with the transgene during the plastid transformation process or, alternatively, from an endogenous plastidial promoter such that an extension of an existing plastidial operon is achieved (Herz et al., Transgenic Research, 2005, 14, 969-982). Inducible gene expression from the plastid genome using a synthetic riboswitch has also been reported (Verhounig et al. (2010), Proc Natl Acad Sci USA 107: 6204-6209). Methods for designing plastid transformation vectors are described by Lutz et al. (Lutz et al., Plant Physiol, 2007, 145, 1201-10).

Recombinase technologies which are useful for producing the disclosed transgenic plants include the cre-lox, FLP/FRT and Gin systems. Methods by which these technologies can be used for the purpose described herein are described for example in (U.S. Pat. No. 5,527,695; Dale And Ow, 1991, Proc. Natl. Acad. Sci. USA 88: 10558-10562; Medberry et al., 1995, Nucleic Acids Res. 23: 485-490).

D. Methods for Reproducing Transgenic Plants

Following transformation by any one of the methods described above, the following procedures can be used to obtain a transformed plant expressing the transgenes: select the plant cells that have been transformed on a selective medium; regenerate the plant cells that have been transformed to produce differentiated plants; select transformed plants expressing the transgene producing the desired level of desired polypeptide(s) in the desired tissue and cellular location.

In plastid transformation procedures, further rounds of regeneration of plants from explants of a transformed plant or tissue can be performed to increase the number of transgenic plastids such that the transformed plant reaches a state of homoplasmy (all plastids contain uniform plastomes containing transgene insert).

The cells that have been transformed may be grown into plants in accordance with conventional techniques. See, for example, McCormick et al. Plant Cell Reports 5:81-84 (1986). These plants may then be grown, and either pollinated with the same transformed variety or different varieties, and the resulting hybrid having constitutive expression of the desired phenotypic characteristic identified. Two or more generations may be grown to ensure that constitutive expression of the desired phenotypic characteristic is stably maintained and inherited and then seeds harvested to ensure constitutive expression of the desired phenotypic characteristic has been achieved.

In some scenarios, it may be advantageous to insert a multi-gene pathway into the plant by crossing of lines containing portions of the pathway to produce hybrid plants in which the entire pathway has been reconstructed. This is especially the case when high levels of product in a seed compromises the ability of the seed to germinate or the resulting seedling to survive under normal soil growth conditions. Hybrid lines can be created by crossing a line containing one or more PHB genes with a line containing the other gene(s) needed to complete the PHB biosynthetic pathway. Use of lines that possess cytoplasmic male sterility (Esser, K. et al., 2006, Progress in Botany, Springer Berlin Heidelberg. 67, 31-52) with the appropriate maintainer and restorer lines allows these hybrid lines to be produced efficiently. Cytoplasmic male sterility systems are already available for some Brassicaceae species (Esser, K. et al., 2006, Progress in Botany, Springer Berlin Heidelberg. 67, 31-52). These Brassicaceae species can be used as gene sources to produce cytoplasmic male sterility systems for other oilseeds of interest such as Camelina.

E. Methods and Compositions for Increasing Germination

The serendipitous discovery that high PHB levels can be achieved in transgenic oilseeds expressing the PHA biosynthesis genes and that this results in significant impairment of subsequent germination and early plant development provides a clear demonstration that commercial levels of PHA can be produced in transgenic oilseeds and in addition presents additional opportunities to understand and control those factors effecting the germination process. In many cases we have observed that seed germination does take place but early plant development is significantly impaired resulting ultimately in dead plants. We have also demonstrated that seeds containing high levels of PHB can be propagated using tissue culture methods providing sucrose as a carbon source. Based on the observation of strong chlorosis and in many cases bleaching of the initial first cotyledons, it is possible that the presence of high levels of PHB in the oilseed plastids may negatively impact chloroplast formation in the cotyledons such that they become chlorotic. One possible solution to this would be to express PHB degradation enzymes during seed germination and the early stages of plant development. In some examples we demonstrate that expressing a PHB polymerase in high PHB producing lines has some benefits in terms of germination and survival. Another possibility is that expression of PHB genes necessary for high PHB requires strong seed specific promoters and the expression from these promoters may carry over into the early stages of seed germination and early plant development. The expression of the PHB genes during germination could divert stored carbon to PHB instead of plant development. Possible solutions to this include inhibiting expression of the PHB genes during germination and early plant development using additional transgene(s) encoding siRNA genes to inhibit expression of one or more of the PHB genes during germination and early development. An alternative solution is to use different seed specific promoters whose expression profile is high enough during seed development to achieve PHB levels of greater 8% but whose expression is low enough during germination and early seed development that the plant is not affected. These alternative promoters can be used to control the expression of one or more of the PHA biosynthetic genes. In some of our Examples described herein we have identified a series of promoters for this approach.

Another possible scenario is that both the presence of PHB and/or expression of PHB genes during germination impairs photosynthesis during the critical stages of germination and early plantlet development resulting in failure of the seedlings to survive. The first two cotyledons of high PUB producers do become chlorotic or bleached. A possible solution to this would be to express additional transgenes encoding enzymes involved in the photosynthetic pathway to enhance photosynthetic flux of carbon. One example of such an enzyme is the cyanobacterial FBPase/SBPase. Each of these possible solutions can be used alone or in combination to generate viable oilseed plants which can germinate and survive normally in the field at levels of at least 25%, 50%, 75% or 100% of the unmodified parental line and produce PHA at greater than 8% by weight of the seed.

III. Methods for Use

The disclosed genetic constructs can be used to produce industrial oilseed plants for high levels of PHA production. Specifically, PHA is produced in the seed.

The transgenic plants can be grown and harvested. The polyhydroxyalkanoate can be isolated from the oilseeds and the remaining plant material can be used as a feedstock for industrial use, preferably for the production of oleochemicals, energy or for use as feed for animals. The polyhydroxyalkanoate harvested from the plants can then be used to produce plastics, rubber material, coating material, and binders for paints, or as a feedstock for producing chemical derivatives such as hydroxyacids, esters, alkenoic acids or amines. PHA also has several medical applications.

The present invention will be further understood by reference to the following non-limiting examples.

EXAMPLES Example 1 Design and Construction of Transformation Vectors for Production of PHB in Oilseeds

Five different vectors for seed specific expression of the PHB pathway were constructed containing different seed specific promoters for production of PHB in oilseeds (Table 1). Vector pMBXS490, a pCAMBIA based plasmid (Centre for Application of Molecular Biology to International Agriculture, Canberra, Australia), contains the following gene expression cassettes: (1) an expression cassette for PHA synthase containing the promoter from the soybean oleosin isoform A gene, a DNA fragment encoding the signal peptide of the small subunit of rubisco from pea (P. sativum) and the first 24 amino acids of the mature protein (Cashmore, A. R. 1983, In Genetic Engineering of Plants, pp. 29-38), a DNA fragment encoding a hybrid PHA synthase (PhaC; U.S. Pat. No. 6,316,262) in which the first nine amino acids at the N-terminus of this synthase are derived from the Pseudomonas oleovorans phaC1 gene and the remainder of the synthase coding sequence is derived from Zoogloea ramigera phaC gene, and the 3′ termination sequence from the soybean oleosin isoform A gene; (2) an expression cassette for reductase containing the promoter from the soybean oleosin isoform A gene, a DNA fragment encoding the signal peptide and the first 24 amino acids of the mature protein of the small subunit of rubisco from pea, a DNA fragment encoding a NADPH dependent reductase (PhaB) from Ralstonia eutropha eutropha (Peoples, O. & A. Sinskey, 1989, J. Biol. Chem., 264, 15293-15297), and the 3′ termination sequence from the soybean oleosin isoform A gene; (3) an expression cassette for thiolase containing the promoter from the soybean glycinin (gy1) gene (Iida et al., 1995, Plant Cell Reports, 14, 539-544), a DNA fragment encoding the signal peptide and the first 24 amino acids of the mature protein of the small subunit of rubisco from pea, the phaA gene encoding a β-ketothiolase (PhaA) from Ralstonia eutropha (Peoples, O. & A. Sinskey, 1989, J. Biol. Chem., 264, 15293-15297), and a 3′ termination sequence from the soybean glycinin gene; (4) an expression cassette for DsRed, a protein that can be visualized in seeds by placing them in light of the appropriate wavelength, containing the promoter from the cassaya mosaic virus (CMV), a DNA fragment encoding a modified red fluorescent protein from Discosoma sp. (DsRed) in which eleven amino acids have been added to the C-terminus to increase solubility and/or prevent aggregation of the protein, and a termination sequence from the Agrobacterium tumefaciens nopaline synthase gene.

TABLE 1

Summary of transformation vectors containing
seed specific promoters

	Promoter controlling	Selectable or
Plasmid	expression of pha genes	visible marker

pMBXS490	Oleosin	DsRed
pMBXS364	LH	DsRed
pMBXS355	LH	bar
pMBXS491	Napin	DsRed
pMBXS492	Glycinin	DsRed

Promoters are as follows: LH, promoter from the Lesquerella fendleri bifunctional oleate 12-hydroxylase:saturate gene (U.S. Pat. No. 6,437,220 Bi); Oleosin, promoter from the soybean oleosin isoform A gene (Rowley and Herman, 1997, Biochim. Biophys. Acta 1345, 1-4); Napin, promoter from the Brassica napus napin gene (Ellenstrom, M. et al., 1996, Plant Molecular Biology, 32: 1019-1027); Glycinin, promoter from the soybean glycinin (gy1) gene (fida, A. et al., 1995, Plant Cell Reports, 14, 539-544).

Vectors pMBXS364, pMBXS355, pMBXS491, and pMBXS492 contain the same PHB pathway genes as pMBXS490 with the exception that the expression of these genes is under the control of different promoters as outlined in Table 1. Vector pMBXS355 contains an expression cassette for the bar gene, encoding phosphinothricin acetyltransferase whose expression is under the control of the 355 promoter. Expression of the bar gene allows selection of transformants based on their resistance to bialaphos. All other vectors in Table 1 contain expression cassettes for DsRed allowing the identification of transgenic seeds under the appropriate wavelength of light.

Example 2 Transformation of Camelina

In preparation for plant transformation experiments, seeds of Camelina sativa cultivar Suneson or Celine were sown directly into 4 inch pots filled with soil (Metro mix) in the greenhouse. Growth conditions were maintained at 24° C. during the day and 18° C. during the night. Plants were grown until flowering. Plants with a number of unopened flower buds were used in ‘floral dip’ transformations.

Agrobacterium strain GV3101 was transformed with the construct of interest using electroporation. A single colony of GV3101 containing the construct of interest was obtained from a freshly streaked plate and was inoculated into 5 mL LB medium. After overnight growth at 28° C., 2 mL of culture was transferred to a 500-mL flask containing 300 mL of LB and incubated overnight at 28° C. Cells were pelleted by centrifugation (6,000 rpm, 20 min), and diluted to an OD600 of ˜0.8 with infiltration medium containing 5% sucrose and 0.05% (v/v) Silwet-L77 (Lehle Seeds, Round Rock, Tex., USA). Camelina plants were transformed by “floral dip” using transformation constructs as follows. Pots containing plants at the flowering stage were placed inside a 460 mm height vacuum desiccator (Bel-Art, Pequannock, N.J., USA). Inflorescences were immersed into the Agrobacterium inoculum contained in a 500-ml beaker. A vacuum (85 kPa) was applied and held for 5 min. Plants were removed from the desiccator and were covered with plastic bags in the dark for 24 h at room temperature. Plants were removed from the bags and returned to normal growth conditions within the greenhouse for seed formation.

To identify Camelina seeds expressing DsRed, fully mature seeds were harvested from transformed plants and placed in a desiccator with anhydrous calcium sulfate as desiccant for at least 2 days prior to screening. DsRed expressing seeds were visualized in a darkroom with a green LumaMax LED flashlight (Lab Safety Supply, Inc., Janesville, Wis.) and a pair of KD's Dark Red glasses (Pacific Coast Sunglasses Inc., Santa Maria, Calif.).

To identify bialaphos resistant seeds, seeds from floral dip transformations were sterilized in 70% ethanol and 10% bleach, and washed in water. Sterilized seeds were placed on germination and selection medium in square Petri dishes. The germination and selection medium contained 10 mg/L bialaphos (Gold BioTechnology, B0178-500) in ½×MS medium, which was made with Murashige & Skoog medium mixture (Caisson Labs, MSP09) at half concentration. The plates were sealed and placed in a growth chamber for germination under a 16-h photoperiod, 3,000 lux light intensity, and temperatures of 23/20° C. at day/night. Seedlings with greenish cotyledons were picked and transferred to soil about six days after initiation of germination.

Example 3 Production of PHB in Seeds of Camelina

In initial transformation experiments with pMBXS490, 24 DsRed positive seeds were isolated. Four of these seeds were sacrificed to determine their PHB content using a previously described gas chromatography/butanolysis technique performed essentially as previously described (Somleva et al., 2008, Plant Biotechnol. J., 663-678). These four seeds contained 19.9, 12.0, 9.8, and 6.4% dwt PHB in the seed. When other seeds from this transformation were planted in soil, seedlings possessed whitish cotyledons and their growth was severely impaired. Only a few T₁seeds with low levels of PHB were capable of germination and survival in soil in a greenhouse. These seedlings were still weak and possessed white or variegated cotyledons.

In transformations of pMBXS355 and pMBXS364, seeds from transformed plants were screened for resistance to bialophos and or visual screening for DsRed, respectively. Despite having the same promoter controlling the expression of the PHB biosynthetic pathway, the maximum PHB production in pMBXS355 (0.54% PHB) was significantly lower than the amount produced by pMBXS364 (3.4%) (Table 2). This is likely due to difficulty in distinguishing between weak pMBXS355 seedlings that produced higher levels of PHB and the non-transformed, bialophos sensitive seedlings.

TABLE 2

Comparison of PHB production in Lines isolated
using bialaphos selection or visual screening

	Selectable or	#of	#of Lines w/	Range of PHB
	Screenable	Lines	PHB in T2	Production
Vector	Marker	Tested	Seeds	(% seed weight)

pMBXS355	Bar¹	204	5	0.05 to 0.54%
pMBXS364	DsRed
²	170	85	0.5 to 3.4%

¹Selection of transformants performed by germination of seeds on tissue culture plates containing 10 mg/L bialaphos.
²Selection of transformants performed by visual screening for DsRed expression.

In transformations with pMBX491 and pMBX492 containing the PHB genes under the control of the napin and glycinin promoters, respectively, were healthier than transformants obtained from pMBX490 transformations. For pMBX491, T2 seeds were isolated containing 8% PHB in DsRed seeds picked from the segregating population. These seeds possessed a 75% germination rate and a 60% survival rate under greenhouse conditions in soil. The cotyledons after 11 days were chlorotic and the growth of this line was significantly delayed compared to wild-type. For pMBX492, T2 seeds were isolated containing 6.9% PHB in DsRed seeds picked from the segregating population. These seeds possessed a 75% germination rate and a 70% survival rate under greenhouse conditions in soil. After 11 days, the cotyledons and first true leaves of this transformant were green. The growth of this line was somewhat delayed compared to wild-type but faster than the pMBXS491 line.

The 19% dwt PHB produced in a single seed obtained from Camelina plants transformed with construct pMBXS490 was an unexpected result and is the highest level of PHB reported in oilseeds to date. Previous studies with Brassica napus produced up to 73% dwt PHB. These seeds were obtained from transformation of Brassica napus using stem segments as the explants and selection of the transformed explants (Fry, J. et al., 1987, 6, 321-325) using glyphosate resistance obtained from expression of a gene encoding 5-enolpyruvylshikimate-3-phosphate synthase. Researchers did not report any germination issues with seeds isolated from the transformed plants [Houmiel et al., 1999, Planta, 209, 547-550; Valentin et al., 1999, Int. J. Biol. Macromol. 25, 303-306].

The use of DsRed as a visual marker in Camelina enabled the identification of high PHB producing seeds that would not have germinated in a typical seed screening procedure where an antibiotic or herbicide selectable marker, such as glyphosate resistance, is employed to provide resistance to the selection agent during seed germination and seedling development in tissue culture medium.

Example 4 Transformation of Brassica Napus, Brassica Carinata, and Brassica Juncea

Transformation of Brassica Carinata

Brassica carinata can be transformed using a previously described floral dip method (Shiv et al., 2008, Journal of Plant Biochemistry and Biotechnology 17, 1-4). Briefly constructs of interest are transformed into Agrobacterium strain GV-3101 and cells are grown in liquid medium. Cells are harvested and resuspended in a transformation medium consisting of V2 MS salts, 5% sucrose, and 0.05% Silwet L-77. Brassica carinata plants are grown in a greenhouse until inflorescences develop and approximately 25% of their flowers are opened. Plants are submerged in the prepared Agrobacterium solution for approximately 1 minute, and covered for 24 hours. Plants are returned to the greenhouse and allowed to set seed. Transformed seeds are screened by picking DsRed seeds under the appropriate wavelength of light as described above.

Transformation of Brassica Napus

Brassica seeds are surface sterilized in 10% commercial bleach (Javex, Colgate-Palmolive) for 30 min with gentle shaking. The seeds are washed three times in sterile distilled water and placed in germination medium comprising Murashige-Skoog (MS) salts and vitamins, 3% (w/v) sucrose and 0.7% (w/v) phytagar, pH 5.8 at a density of 20 per plate and maintained at 24° C. an a 16 h light/8 h dark photoperiod at a light intensity of 60-80 μEm⁻²s⁻¹for 4-5 days.

Constructs of interest are introduced into Agrobacterium tumefacians strain EHA101 (Hood et. al., 1986, J. Bacterial. 168: 1291-1301) by electroporation. Prior to transformation of cotyledonary petioles, single colonies of strain EHA101 harboring each construct are grown in 5 ml of minimal medium supplemented with appropriate antibiotics for 48 hr at 28° C. One ml of bacterial suspension was pelleted by centrifugation for 1 min in a microfuge. The pellet was resuspended in 1 ml minimal medium.

For transformation, cotyledons are excised from 4 or in some cases 5 day old seedlings so that they included ˜2 mm of petiole at the base. Individual cotyledons with the cut surface of their petioles are immersed in diluted bacterial suspension for 1 s and immediately embedded to a depth of ˜2 mm in co-cultivation medium, MS medium with 3% (w/v) sucrose and 0.7% phytagar and enriched with 20 μM benzyladenine. The inoculated cotyledons are plated at a density of 10 per plate and incubated under the same growth conditions for 48 h. After co-cultivation, the cotyledons are transferred to regeneration medium comprising MS medium supplemented with 3% sucrose, 20 μM benzyladenine, 0.7% (w/v) phytagar, pH 5.8, 300 mg/L timentinin and 20 mg/L kanamycin sulfate.

After 2-3 weeks regenerant shoots obtained are cut and maintained on “shoot elongation” medium (MS medium containing, 3% sucrose, 300 mg/L timentin, 0.7% (w/v) phytagar, 300 mg/L timentinin and 20 mg/L kanamycin sulfate, pH 5.8) in Magenta jars. The elongated shoots are transferred to “rooting” medium comprising MS medium, 3% sucrose, 2 mg/L indole butyric acid, 0.7% phytagar and 500 mg/L carbenicillin. After roots emerge, plantlets are transferred to potting mix (Redi Earth, W. R. Grace and Co.). The plants are maintained in a misting chamber (75% relative humidity) under the same growth conditions. Plants are allowed to self pollinate to produce seeds. Seeds are screened by visualization of DsRed as described above.

Brassica napus can also be transformed using the floral dip procedure described by Shiv et al. (Shiv et al., 2008, Journal of Plant Biochemistry and Biotechnology 17, 1-4) as described above for Brassica carinata.

Transformation of Brassica Juncea

Brassica juncea can be transformed using hypocotyl explants according to the methods described by Barfield and Pua (Barfield and Pua, Plant Cell Reports, 10, 308-314) or Pandian et al. (Pandian, et al., 2006, Plant Molecular Biology Reporter 24: 103a-103i) as follows.

B. juncea seeds are sterilized 2 min in 70% (v/v) ethanol and washed for 20 min in 25% commercial bleach (10 g/L hypochlorite). Seeds are rinsed 3× in sterile water. Surface-sterilized seeds are plated on germination medium (1×MS salts, 1×MS vitamins, 30 g/L sucrose, 500 mg/L MES. pH 5.5) and kept in the cold room for 2 days. Seeds are incubated for 4-6 days at 24° C. under low light (20 μm m⁻¹s⁻¹). Hypocotyl segments are excised and rinsed in 50 mL of callus induction medium (1×MS salts, 1×B5 vitamins, 30 g/L sucrose, 500 mg/L MES, 1.0 mg/L 2,4-D, 1.0 mg/L kinetin pH 5.8) for 30 min without agitation. This procedure is repeated but with agitation on orbital shaker (˜140 g) for 48 h at 24° C. in low light (10 μm m⁻¹s⁻¹).

Agrobacterium can be prepared as follows: Cells of Agrobacterium strain AGL1 (Lazo, G. et al. (1991) Biotechnology, 9: 963-967) containing the construct of interest are grown in 5 mL of LB medium with appropriate antibiotic at 28° C. for 2 days. The 5 mL culture is transferred to 250 mL flask with 45 mL of LB and cultured for 4 h at 28° C. Cells is pelleted and resuspended in BM medium (1×MS salts, 1×135 vitamins, 30 g/L sucrose, 500 mg/L MES, pH 5.8). The optical density at 600 nm is adjusted to 0.2 with BM medium and used for inoculation.

Explants are cocultivated with Agrobacterium for 20 min after which time the Agrobacterium suspension is removed. Hypocotyl explants are washed once in callus induction medium after which cocultivation proceeds for 48 h with gentle shaking on orbital shaker. After several washes in CIM, explants are transferred to selective shoot-inducing medium (500 mg/L AgNO2, 0.4 mg/L zeatin riboside, 2.0 mg/L benzylamino purine, 0.01 mg/L GA, 200 mg/L Timentin appropriate selection agent and 8 g/L agar added to basal medium) plates for regeneration at 24° C. Root formation is induced on root-inducing medium (0.5×MS salts, 0.5×B5 vitamins, 10 g/L sucrose, 500 g/L MES, 0.1 mg/L indole-3-butyric acid, 200 mg/L Timentin, appropriate selection agent and 8 g/L agar, pH 5.8).

Plantlets are transferred to or removed from agar, gently washed, and transferred to potting soil in pots. Plants are grown in a humid environment for a week and then transferred to the greenhouse.

Example 5 Managing Gene Expression During Germination, RNA Interference Constructs

To control PHB formation during seed germination, a series of RNA interference (RNAi) constructs were designed where the RNAi element was targeted to either synthase, thiolase, or reductase. The RNAi element was designed with an intron between an inverted repeat of the stretch of the gene targeted for RNAi interference. Expression of the RNAi element was controlled by a chemically inducible promoter. A summary of the RNAi constructs is shown in Table 3. All constructs for RNAi interference contain the PHB expression cassettes and DsRed expression cassette of pMBXS490.

TABLE 3

Summary of RNAi interference transformation vectors

	RNAi	Promoter for expression
Vector	interference target	of GRVH

phaA-RNAi/35S	phaA	35S
phaC-RNAi/35S	phaC	35S
phaA-RNAi/glyP	phaA	glycinin promoter
phaC-RNAi/glyP	phaC	glycinin promoter

Plasmid phaA-RNAi/35S contains the following expression cassettes for inducible expression of the RNAi element with homology to a stretch of the phaA gene: (1) an expression cassette for a chimeric ecdysone receptor consisting of the double enhanced version of the 35S promoter from cauliflower mosaic virus, the grvH gene encoding a chimeric ecdysone receptor that contains a DNA-binding domain derived from the human glucocorticoid receptor, the transcriptional activation domain from the Herpes simplex viral protein VP16, and the ligand-binding domain from the ecdysone receptor of Heliothis virescens, and the 3′ termination sequence of the nopaline synthase gene from Agrobacterium tumefaciens; (2) an expression cassette for the RNAi element consisting of a DNA fragment encoding six copies of glucocorticoid response element (GRE) derived from the promoter region of mouse mammary tumor virus (MTV), a minimal promoter (MP) derived from the 35S promoter from cauliflower mosaic virus, a 0.60 kb DNA fragment derived from the gene encoding a β-ketothiolase (PhaA) from Ralstonia eutropha, a 1.13 kb DNA sequence from the intron 1 of fatty acid desaturase 2 (FAD2) from Arabidopsis thaliana, the same 0.6 kb DNA fragment of phaA described previously arranged in an antisense orientation to make a hairpin structure for RNA interference (RNAi), and the 3′ termination sequence of the gene for rib-1,5-bisphospate carboxylase (rbcs) small subunit from pea (P. sativum). The design of this construct contains the necessary genetic components such that upon the addition of inducing agent, the chimeric ecdysone receptor binds to the glucocorticoid response elements located upstream of a minimal 35S promoter and transactivates expression of the RNAi element (FIG. 1). In the absence of inducing agent, some leakiness of the expression from the minimal promoter is expected.

Three additional vectors were made that differed from phaA-RNAi/35S in either the target of their RNAi element or the promoter used for expression of the chimeric ecdysone receptor (GRVH) (Table 3).

Transgenic Camelina plants were produced as described previously and transformed seeds were isolated by visual screening of DsRed expression. Seeds were germinated and plants were grown in a greenhouse and treated with methoxyfenozide inducing agent during flowering and seed formation. A portion of the seed was used for analysis of PHB. Seeds containing 10% PHB were isolated (FIG. 2). T2 seeds were placed on a piece of filter paper and soaked in inducing agent prior to transfer to soil.

T2 seeds from the above transformations were germinated and grown in soil in a greenhouse producing T2 seedlings. Untreated T2 plants were allowed to set seed and T3 seeds from select lines were collected and the polymer content was measured using the previously described gas chromatography/butanolysis procedures. Several lines producing greater than 7% dwt PHB in both the T2 and T3 generations were obtained (FIG. 3). No difference between plants treated with inducing agent or treated with water was observed. This suggests that the inducible promoter element is not controllable under the conditions used for the experiments but that there is some basal level of expression from the minimal promoter in front of the RNAi element.

The germination and survival of select seeds were analyzed under high light conditions (up to 1250 microMoles m⁻²s⁻¹light intensity) at a constant temperature of 14° C. and their survival rate was compared to seeds obtained from pMBXS364 transformations and wild-type seeds (Table 4). Seeds were tested in high light conditions since high PHB producing lines obtained from transformations with pMBXS490 and pMBXS364 in general possess whitish cotyledons that might be impaired in photosynthesis. The lighting program used in the HID chamber was as follows: 6 am to 7 am, 300 microMoles m⁻²s⁻¹; 7 am to 8 am, 750 microMoles M⁻²s⁻¹; 8 am to 3 pm, 1250 microMoles m⁻²s⁻¹; 3 pm to 5 pm, ramp down from 1250 to microMoles m⁻²s⁻¹; 5 pm to 6 am, no light. Under these conditions, 80% of the control wild-type line survived after 18 days under high light growth conditions. None of the pMBXS364 lines survived these growth conditions. The majority of the RNAi lines tested possessed greater than 50% survival, with some as high as 85-95%.

TABLE 4

Survival of RNAi Lines Compared to Wild-type and
pMBXS364 Lines Grown Under High Light Conditions

Transformation			% survivability in high
Construct	Line	% PHB	light growth chamber*

phaA-RNAi/35S	A18	7.15	95
phaC-RNAi/35S	C5	7.92	85
phaA-RNAi/glyP	B12	5.54	85
phaA-RNAi/35S	A8	5.1	85
wild-type	Celine		0	85
phaC-RNAi/35S	C39	6.43	80
phaA-RNAi/glyP	B1	6.5	70
phaA-RNAi/35S	A31	5.5	70
phaA-RNAi/glyP	B15	7.77	60
phaC-RNAi/35S	C28	7.09	60
phaC-RNAi/35S	C47		8	50
phaA-RNAi/35S	A34	7.74	30
phaA-RNAi/35S	A4	7.45	25
phaA-RNAi/glyP	B14	6.1	25
phaC-RNAi/glyP	D29	7.14	0
pMBXS364	284A	4.4	0
pMBXS364	328A		8	0

*20 seeds of each line were planted to measure survivabilty

High PHB containing seeds can be screened for germination ability prior to planting in soil by plating the seeds on wet filter paper to determine if they germinate. If seeds are impaired in germination or possess chlorotic seedlings, this filter paper can be transferred to tissue culture medium containing ½×MS agar medium (prepared from Murashige & Skoog salts with vitamins, Caisson Labs, MSP09) supplemented with 2% sucrose,

Example 6 Managing Gene Expression During Germination, Controlled Polymer Degradation During Germination

To prevent or limit PHB formation during seed germination, constructs were designed containing genes encoding a pathway for controlled polymer degradation during seed germination. PHB production would proceed during seed formation and polymer degradation would occur during seed germination (FIG. 3). Genes encoding PHA depolymerase and 3-hydroxybutyrate dehydrogenase were chosen for degradation of polymer. These genes are expected to convert PHB to 3-hydroxybutyrate and 3-hydroxybutryate to acetoacetate, compounds that could be further metabolized by the germinating seedling. Since construct pMBXS490 enabled high PHB production, albeit with poor germination/seedling survival, it was used as a starting plasmid to build future transformation constructs. Plant transformation construct pMBXVT1, is a pCAMBIA based vector containing seed specific expression of PHA genes and cassettes for expression of the depolymerase and 3-hydroxybutyrate dehydrogenase under the control of germination specific promoters. Expression cassettes for the PHB biosynthetic genes and DsRed are as described for pMBXS490. Additional expression cassettes in pMBXVT1 are as follows: 1) an expression cassette for depolymerase containing the promoter from Vigna mungo sulphydryl-endopeptidase gene (SH-EP promoter; Akasofu et al., 1990 Nucleic Acids Research. 18, 1892), a DNA fragment encoding the signal peptide and the first 24 amino acids of the mature protein of the small subunit of rubisco from pea, a DNA fragment encoding an intracellular polyhydroxybutyrate depolymerase (PhaZal) from Ralstonia eutropha (Saegusa et al., 2001, J. Bacteriol. 183, 94-100), and a termination sequence from the Pisum sativum rbcS-E9 gene; 2) an expression cassette for 3-hydroxybutyrate dehydrogenase containing the SH-EP promoter, a DNA fragment encoding the signal peptide and the first 24 amino acids of the mature protein of the small subunit of rubisco from pea, a DNA fragment encoding D(−)-3-hydroxybutyrate dehydrogenase (hbdh) from Pseudomonas fragi (Ito et al., 2006 J. Mol. Biol. 355, 722-733), and the termination sequence from the Pisum sativum rbcS-E9 gene.

Construct pMBXVT1 was transformed into Camelina as previously described and T₁seeds were selected by visualization of DsRed. T₁seeds were either planted directly into soil or germinated on filter paper and transplanted into soil. The resulting T₂seeds were tested for PHB using the previously described gas chromatography/butanolysis techniques. T₂seeds containing up to 11.3% PHB were isolated (Table 5) however these seeds produced seedlings that did not survive in soil conditions. Germination of T₂seeds on filter paper was measured and the percent survival was calculated. One line containing 5.75% PHB with 100% survival in soil was isolated. Lines that possessed severely impaired germination in soil or on filter paper (i.e. line containing 11.3% PHB) were rescued by germination on tissue culture medium as follows. Seeds were surface sterilized with 70% alcohol for 2 minutes and with 10% commercial bleach for 10 minutes. The seeds were washed thoroughly at least 3 times with sterile water before transferring them on to agar plates. Seeds were cold treated at 4° C. by plating them on agar media containing ½ strength Murashige and Skoog basal salts and Gamborg's vitamins (Sigma Chemical Company, St. Louis, Mo.) supplemented with 2% sucrose. Plates were incubated at 4° C. for 72 hours and then transferred to a tissue culture chamber set at 20° C. Seedlings were transferred to soil once they had obtained true leaves and were then transferred to the greenhouse. T₃seeds were generated from the T₂lines and evaluated for PHB content. A graph comparing T2 and T3 seeds from select lines is shown in FIG. 4.

TABLE 5

% PHB and % Survival in Select Lines
Transformed with Vector pMBXVTI

	% PHB	% Survival
T1	in T2	of T2	T2 seedling
Lines	Seeds	seedlings*	phenotype

18	0	100%	Green
65	2.67	100%	Green
13	4.18	100%	Green
41	5.75	100%	Chlorotic
60	6.13	75%	Chlorotic
24	6.38	0	Albino
61	7.41	0	Albino
39	11.34	0	Albino

*% survival after germination on filter paper, transfer to soil, and growth in a greenhouse

Additional transformation vectors for inducible expression of the PHB depolymerase and 3-hydroxybutyrate dehydrogenase were also constructed. These constructs contain the expression cassettes of pMBXS490 for the PHB biosynthetic pathway and DsRed genes as well as inducible expression cassettes for PHB depolymerase and 3-hydroxybutyrate dehydrogenase. The inducible expression cassettes rely on the binding of a chimeric receptor (VP16:GAL4:CfEcR gene), whose expression is under the control of a constitutive promoter, to the inducing agent and response element (FIG. 1). The chimeric receptor contains a transcriptional activation domain from Herpes simplex viral protein (VP16 AD), a binding domain from yeast GAL4 transcription activator (GAL4 DBD), and a ligand binding domain from the Choristoneura fumiferana ecdysone receptor (CfEcR). This binding initiates transcription of the PHB depolymerase and 3-hydroxybutyrate dehydrogenase genes placed behind a DNA sequence containing a minimal 35S promoter with five copies of the 19 bp yeast GAL4 response elements upstream of the minimal promoter for chemical induction. Upon addition of a chemical inducing agent, the chimeric receptor protein transactivates expression of the target gene(s) cloned under the control of the GAL4 response elements and the minimal promoter. Four separate constructs were constructed that differ in the length of their minimal promoter sequence and/or the promoter that drives the expression of the chimeric receptor (Table 6).

TABLE 6

Inducible promoter constructs for expression of PIM
depolymerase and 3-hydroxybutyrate dehydrogenase.

	Minimal
	promoter	Promoter driving expression
Vector	sequence	of chimeric receptor*

pMBXVT3	−46	MMV promoter
pMBXVT4	−31	MMV promoter
pMBXVT5	−46	SH-EP promoter
pMBXVT6	−31	SH-EP promoter

*MMV promoter, constitutive promoter from mirabilis mosaic virus
SH-EP promoter, germination specific promoter from Vigna mungo* sulphydryl-endopeptidasegene

With these constructs, the addition of inducing agent was expected to yield good expression of the PHB depolymerase and 3-hydroxybutyrate dehydrogenase at the growth stage in which the inducing agent was applied. In the absence of inducing agent, a basal level of expression due to the leakiness of the promoter was expected.

Constructs were transformed into Camelina, using the transformation methods described above, and the chemical inducing agent was applied from flowering to harvest of the T₁seeds. The chemical inducing agent used for this purpose was methoxyfenozide applied to the plants in the form of the commercial pesticide Intrepid (Dow AgroSciences, Indianapolis, Ind.). Concentrations for application ranged from 66 to 100 μM. Intrepid was also applied during germination of T₁seeds, and again from flowering to harvest of the T₂seeds. The T₂seeds were then split into two groups. The first received no inducing agent (allowing the accumulation of PHB in the seeds). The other was treated with the inducing agent to limit PHB accumulation in the seeds, possibly improving seed germination. No significant difference in the levels of PHB in seeds that had been treated with Intrepid during flowering and seed development were observed compared to controls.

The survival of T₂seedlings was determined by germinating seeds on filter paper and then transferring seedlings to soil (Table 7). T₂seeds with poor germination were rescued by germinating on ½ strength Murashige and Skoog basal salts with Gamborg's vitamins supplemented with 2% sucrose as described above. Lines were grown in the greenhouse to produce T₃seeds.

TABLE 7

% PHB and % Survival in Select Lines Transformed with
Vectors pMBXVT3, pMBXVT4, pMBXVT5, and pMBXVT6

		% PHB	Survival of
	Ti	in T2	T2	T2 seedling
Construct	Line	seeds	seedlings*	phenotype

pMBXVT3

	2	0	100%	Green
	66	2.39	100%	Chlorotic
	71	7.11	35%	Chlorotic
	72	7.66	0	Albino
	70	8.17	75%	Chlorotic
	74	9.51	0	Albino
pMBXVT4	36	0	100%	Green
	42	4.53	100%	Chlorotic
	48	8.04	30%	Albino
	49	8.34	0	Albino
	54	9.1	70%	Albino-chlorotic
	56	9.14	30%	Chlorotic
	22	9.6	0	Albino
	57	12.32	0	Albino
pMBXVT5	4	0	100%	Green-chlorotic
	15	2.74	100%	Chlorotic
	10	9.24	0	Albino
pMBXVT6
	1	0	100%	Green
	6	3.46	100%	Chlorotic
	9	8.86	10%	Albino
	8	10.19	0	Albino
	5	10.75	0	Albino

*% survival after germination on filter paper, transfer to soil, and growth in a greenhouse.

Since the T₂seeds from these lines had in general better germination and seedling viability than seeds obtained from transfounations with plasmid pMBXS490, leaky expression from the inducible promoter controlling the expression of depolymerase and 3-hydroxybutyrate dehydrogenase may have occurred such that sufficient amounts of these enzymes are produced to increase germination and seedling viability of high PHB producing seeds without significantly compromising PHB yield.

T₂seeds that were unable to germinate and survive on filter paper were rescued by germinating on ½ strength Murashige and Skoog basal salts with Gamborg's vitamins supplemented with 2% sucrose and 15 μM methoxyfenozide as described above. All lines were grown in the greenhouse to produce T₃seeds.

High PHB containing seeds can be screened for germination ability by plating the seeds on wet filter paper to determine if they germinate. If seeds are impaired in germination or possess chlorotic seedlings, this filter paper can be transferred to tissue culture medium containing ½×MS agar medium (prepared from Murashige & Skoog salts with vitamins, Caisson Labs, MSP09) supplemented with 2% sucrose,

Example 7 Expression of Depolymerase and 3-Hydroxybutyrate Dehydrogenase using a Heat Shock Promoter

Plasmid pMBXS430 was prepared to test the use of a heat shock inducible promoter to control expression of depolymerase and 3-hydroxybutyrate dehydrogenase genes. This plasmid is the same as pMBXVT1 with the exception that the germination specific promoter controlling the expression of depolymerase and 3-hydroxybutyrate dehydrogenase genes has been replaced by a heat shock inducible promoter from the soybean small heat shock (Gmhsp17.5E) gene (Czarnecka, E. et al., 1989, Mol. Cell. Biol. 9, 3457-3463). Plasmid pMBXS430 was transformed into Camelina according to the methods described above and seeds were screened for DsRed expression. Isolated T₁seeds were germinated on ½×MS agar medium (Murashige & Skoog salts with vitamins, Caisson Labs, MSP09) supplemented with 2% sucrose, transferred to soil in the greenhouse, and allowed to set seed. T₂seeds were analyzed for PHB levels (FIG. 26). Up to 11.63% PHB was obtained. A homozygous plant derived from this line produced up to 11.64% PHB in T3 seeds.

Example 8 Production of Hybrid Lines that are not Capable of Germinating

In previous experiments in Arabidopsis, lower levels of PHB were obtained when lines expressing individual PHB genes were crossed to produce a plant containing the entire PHB biosynthetic pathway (Nawrath, C., Y. Poirier, et al., 1994, Proc. Natl. Acad. Sci. USA 91, 12760-12764) than when multi-gene constructs containing the entire PHB biosynthetic pathway were constructed and transformed (Bohmert, K., I. et al., 2000, Planta 211, 841-845;U.S. Pat. No. 6,448,473). This observation led to the subsequent predominant use of multi-gene constructs for PHB production in plants. However, in some scenarios, it may be advantageous to insert a multi-gene pathway into the plant by crossing of lines containing portions of the pathway to produce hybrid plants in which the entire pathway has been reconstructed. This is especially the case when high levels of product in a seed compromises the ability of the seed to germinate or the resulting seedling to survive under normal soil growth conditions. Hybrid lines can be created by crossing a line containing one or more PHB genes with a line containing the other gene(s) needed to complete the PHB biosynthethic pathway. Use of lines that possess cytoplasmic male sterility (Esser, K. et al., 2006, Progress in Botany, Springer Berlin Heidelberg. 67, 31-52) with the appropriate maintainer and restorer lines allows these hybrid lines to be produced efficiently. Cytoplasmic male sterility systems are already available for some Brassicaceae species (Esser, K. et al., 2006, Progress in Botany, Springer Berlin Heidelberg. 67, 31-52). These Brassicaceae species can be used as gene sources to produce cytoplasmic male sterility systems for other oilseeds of interest such as Camelina. Cytoplasmic male sterility has also been reported upon expression of a β-ketothiolase from the chloroplast genome in tobacco (Ruiz, O. N. and H. Daniell, 2005, Plant Physiol. 138, 1232-1246). Male sterility has also been reported upon expression of the faoA gene encoding the α-subunit of the fatty acid β-oxidationcomplex from Pseudomonas putida (U.S. Pat. No. 6,586,658).

High PHB producing lines that are not capable of germination can be produced using oilseed lines that possess cytoplasmic male sterility (CMS) controlled by an extranuclear genome (i.e. mitochondria or chloroplast). The male sterile line is typically maintained by crossing with a maintainer line that is genetically identical except that it possesses normal fertile cytoplasm and is therefore male fertile. Transformation of the maintainer line with one or more genes for the PHB biosynthetic pathway and crossing this modified maintainer line [FIG. 5, M line (phaA and phaC)] with the original male sterile line [FIG. 5, S line (CMS)] will produce a male sterile line possessing a portion of the PHB biosynthetic pathway. In this example, insertion of the phaA and phaC genes into the maintainer line and crossing with the original male cytoplasmic sterile line will form a male sterile line containing the phaA and phaC genes [FIG. 5, S line, (phaA and phaC)].

Fertility can be restored to this line using a “restorer line” that carries the appropriate nuclear restorer genes. Alternatively, the restorer line can be transformed with the remaining genes required to complete the PHB biosynthetic pathway [FIG. 5, R line (phaB)] and crossed with the previously created male sterile line containing phaA and phaC [FIG. 5, S line (phaA and phaC)] to produce a hybrid line containing the entire PHB biosynthetic pathway [FIG. 5, Hybrid seeds (phaA, phaB, and phaC)].

Crosses can be performed in the field by planting multiple rows of the male sterile line, the line that will produce the seed, next to a few rows of the male fertile line. Harvested seed can be used for subsequent plantings or as the PHB containing seed for crushing and extraction. When expression cassettes for the PHB genes in this example are controlled by strong promoters, such as the soybean oleosin promoter, high PHB producing seeds generated in this manner will possess weak seedlings upon germination and will not be able to survive field conditions under normal growth circumstances unless treated with a material that promotes seedling strength/vigor. This adds a level of gene containment.

Cytoplasmic male sterility systems are already available for some Brassicaceae species (Esser, K., 2006, Progress in Botany, Springer Berlin Heidelberg. 67, 31-52). These Brassicaceae species can be used as gene sources to produce cytoplasmic male sterility systems for other oilseeds of interest such as Camelina. Cytoplasmic male sterility has also been reported upon expression of a β-ketothiolase from the chloroplast genome in tobacco (Ruiz, O. N. and H. Daniell, 2005, Plant Physiol. 138, 1232-1246). Overexpression of β-ketothiolase in Camelina to generate a male sterile line and subsequent crossing with a line expressing phaB and phaC could also be used for hybrid seed production.

Male sterile lines have also been produced in Brassica napus by overexpression of the faoA gene from Pseudomonas putida under the control of the a phaseolin promoter sequence (U.S. Pat. No. 6,586,658).

Double haploid technology can be used to speed up the breeding process. In the double haploid technique, immature pollen grains (haploids) are exposed to treatments that result in doubling of the existing genetic material resulting in homozygous, true breeding material in a single generation.

Example 9 Improved Germination Efficiency of High PHB Producing Seeds Using Promoters that are not Active or Minimally Active During Seed Germination and Seedling Development

Use of a promoter for expression of PHB genes that is active during seed development but inactive or minimally active during seed germination and seedling development would allow the production of high PHB producing seeds that can readily germinate under field conditions. To determine if candidate promoters in our PHB production constructs were active during germination, each promoter was put in an expression cassette with the reporter gene β-glucuronidase (GUS). Seedlings were germinated and seedlings were stained with X-Gluc (5-bromo-4-chloro-3-indolylbeta-D-glucuronide). GUS expression was observed with all seed specific promoters tested in germinating seedlings (Table 8). In addition, promoters from the lesquerella hydroxylase gene, the napin gene, and the glycinin gene yielded GUS staining in their first true leaves.

TABLE 8

GUS expression patterns of seed specific promoters during
seed formation and germination.

		GUS expression during seed
	GUS expression during	germination, Days after Germination
	seed formation, Days after	(DAG)

flowering (DAF)

Staining in true leaf

Promoter	4 DAF	6 DAF	8 DAF	10 DAF	12 DAF	1 DAG	10 DAG	(7 to 10 DAG)

35S	ND*	ND	ND	ND	ND		8	8	8
LH	0	1	3	8	9.5	8	8	8
Oleosin	0.5	1.2	1.5	7	10	8	8	0
P3	0	2	3	6	10	8	8	0
Napin	3	4	9	10	10	8	8	8
Glycinin	3	4	9	10	10	8	8	8

*ND, not determined;
Numbers represent qualitative, visual measurement of staining intensity (0 = no staining, 10 = dark blue staining).
Promoters are as follows: 35S, promoter from the cauliflower mosaic virus 35S gene; LH, promoter from the Lesquerella fendleri bifunctional oleate 12-hydroxylase:saturate gene; Oleosin, promoter from the soybean oleosin isoform A gene; P3, promoter from a seed specific gene in Arabidopsis thaliana (U.S. Pat. No. 7,405,345); Napin, promoter from the Brassica napus napin gene; Glycinin, promoter from the soybean glycinin (gyl) gene.

A search for candidate promoters that were active during seed development but inactive or minimally active during seed germination was performed using a filtered DNA mircroarray dataset of 9,611 genes from Arabidopsis (Le et al., 2010, Proc. Natl. Acad. Sci. USA, 107, 8063-8070).

Unbiased hierarchical clustering (Eisen et al., 1998, Proc. Natl. Acad. Sci. USA 95:14863-14868) of the filtered microarray dataset was performed with five manually defined reference profiles (Table 9). Reference profile 1 was set to be highly expressed at the 24-h post-pollination seed. Reference profiles 2 and 3 were set to be highly expressed in both the globular-stage and cotyledon-stage seed, since these stages are developmentally close and were identified to exhibit similar expression patterns. Reference profiles 4 and 5 were also set to be highly expressed in both the mature-green-stage and postmature-green-stage seed. All non-seed stages, including the unfertilized ovule, seedling, leaf, root, stem, and floral buds were set to zero.

TABLE 9

Predefined search profiles to identify genes with similar
expression patterns.

Reference
Profiles	OV	24H	GLOB	COT	MG	PMG	SDLG	L	R	S	F

Ref1_24H

	0	10,000	1,000	500	200	20	0	0	0	0	0
Ref2_GLOB	0	1,000	10,000	5,000	200	20	0	0	0	0	0
Ref3_COT	0	200	5,000	10,000	200	20	0	0	0	0	0
Ref4_MG	0	50	200	200	10,000	5,000	0	0	0	0	0
Ref5_PGM	0	50	200	200	5,000	10,000	0	0	0	0	0

*Abbreviations are as follows: OV, unfertilized ovule; 24H, 24-h postpollination seed; GLOB, globular-stage seed; COT, cotyledon-stage seed; MG, mature-green-stage seed; PMG, postmature-green-stage seed; SDLG, seedling; L, leaf; R, root; S, stem; F, floral buds.

Hierarchical clustering analysis identified several genes which showed similar expression patterns as the five reference profiles. Genes with expression values in non-seed stages were removed from the set of identified genes. 81 genes whose promoter region may be suitable for PHB production in seeds with little to no PHB gene expression in seedlings were identified (Table 10).

TABLE 10

Genes in Arabidopsis thaliana with the pre-defined seed specific
expression profiles identified by genome-wide similarity analysis.

						Functional
AGI ID	24H	GLOB	COT	MG	PMG	Category	Descriptions

24H genes (ref1_24H)

AT4G13090	303					Cell	xyloglucan:xyloglucosyl
						Structure	transferase,

GLOB genes (ref2_GLOB)

AT3G28490		155		Secondary	oxidoreductase, 2OG-Fe(II)
				Metabolism	oxygenase family
					protein
AT3G03260		505	165	Transcription	homeobox-leucine
					zipper family protein/
					lipid-binding START
					domain-containing
					protein
AT5G09490		1019	438	Protein	40S ribosomal protein
				Synthesis	S15 (RPS15B)
AT2G17750		1045	449	Unclassified-	similar to unknown
				Proteins	protein [Arabidopsis
				With cDNA	thaliana]
				Support
AT2G43660		1477	614	Cell	glycosyl hydrolase
				Structure	family protein 17
AT5G46040	423	2556	1110	Transporter	proton-dependent
					oligopeptide transport
					(POT) family protein
AT5G46820;		3108	1072	Protein	similar to unknown
AT5G46810				Destination &	protein [Arabidopsis
				Storage	thaliana]
AT1G49800		4482	1552	Unclassified-	unknown protein
				Proteins
				With cDNA
				Support

COT genes (ref3_COT)

AT2G26320		108	191		Transcription	MADS-box protein
						(AGL33)
AT5G63740		121	196		Unclassified-	zinc finger protein-
					Proteins With	related
					Unknown
					Function
AT5G23650		158	301		Transcription	myb family
						transcription factor
AT4G22400		324	305		Unclassified-	similar to unknown
					Proteins With	protein [Arabidopsis
					cDNA Support	thaliana]
						(TAIR:AT4G18320.1)
AT1G20730		196	308		Unclassified-	similar to metal ion
					Proteins With	binding [Arabidopsis
					Unknown	thaliana]
					Function
AT4G29620		315	322		Metabolism	cytidine deaminase,
						putative/cytidine
						aminohydrolase,
						putative
AT1G61330;		304	327		Unclassified-	[AT1G61330, F-box
AT1G61320					Proteins With	family protein]
					Unknown
					Function
AT1G16980		349	441		Metabolism	ATTPS2 (Arabidopsis
						thaliana trehalose-
						phosphatase/synthase
						2);
AT1G61090		242	471		Unclassified-	similar to unknown
					Proteins With	protein [Arabidopsis
					cDNA Support	thaliana]
						(TAIR:AT1G61095.1)
AT3G03410		464	755		Signal	calmodulin-related
					Transduction	protein, putative
AT2G03190		688	873		Protein	ASK16
					Destination &	(ARABIDOPSIS
					Storage	SKP1-LIKE 16);
						ubiquitin-protein ligase
AT1G62340		561	965		Protein	ALE1 (ABNORMAL
					Destination &	LEAF SHAPE 1);
					Storage	subtilase
AT5G39440		634	1356		Signal	SnRK1.3 (SNF1-
					Transduction	RELATED PROTEIN
						KINASE 1.3); kinase
AT2G20160	235	1118	1390		Protein	MEO (MEIDOS);
					Destination &	ubiquitin-protein ligase
					Storage
AT5G07260		908	1564	472	Transcription	homeobox protein-
						related
AT5G10220		1539	1834		Intracellular	ANN6 (ANN6,
					Traffic	ANNEXIN
						ARABIDOPSIS 6);
AT2G32370		1208	2373		Transcription	homeobox-leucine
						zipper family protein

MG genes (ref4_MG)

AT3G29190			374		Secondary	terpene synthase/cyclase
					Metabolism	family protein
AT5G20420			411		Transcription	CHR42 (chromatin
						remodeling 42); ATP
						binding/DNA binding/
						helicase
AT1G65670			548		Metabolism	CYP702A1
						(CYTOCHROME P450,
						FAMILY 702,
						SUBFAMILY A,
						POLYPEPTIDE 1);
						oxygen binding
AT1G25270		74	669	291	Unclassified-	similar to nodulin
					Proteins	MtN21 family protein
					With	[Arabidopsis thaliana]
					Unknown
					Function
AT3G04370			675	354	Protein	similar to 33 kDa
					Destination &	secretory protein-related
					Storage	[Arabidopsis thaliana]
AT5G20860			918	468	Cell	pectinesterase family
					Structure	protein
AT1G19200			923	480	Metabolism	senescence-associated
						protein-related
AT3G02940			1058	504	Transcription	MYB107 (myb domain
						protein 107); DNA
						binding/transcription
						factor
AT3G04190;			1503	613	Protein	[AT3G04190, germin-
AT3G04180					Destination &	like protein,
					Storage	putative];[AT3G04180,
						germin-like protein,
						putative]
AT4G26200	110	532	1899	1372	Secondary	ACS7 (1-Amino-
					Metabolism	cyclopropane-1-
						carboxylate synthase 7)
AT4G25980			1922	673	Disease &	cationic peroxidase,
					Defense	putative
AT3G44460		131	2459	1602	Transcription	DPBF2 (BASIC
						LEUCINE ZIPPER
						TRANSCRIPTION
						FACTOR 67)
AT5G07500		283	2533	1287	Transcription	PEI1; nucleic acid
						binding/transcription
						factor
AT1G09500	167	238	3736	1929	Cell	cinnamyl-alcohol
					Structure	dehydrogenase family/
						CAD family
AT3G26790	110	1666	4347	3489	Transcription	FUS3 (FUSCA 3); DNA
						binding/transcription
						factor
AT3G04170			5495	2836	Disease &	germin-like protein,
					Defense	putative
AT5G09640		294	6073	5155	Protein	SNG2
					Destination &	(SINAPOYLGLUCOSE
					Storage	ACCUMULATOR 2);
						serine carboxypeptidase
AT2G41400;			6470	3905	Unclassified-	[AT2G41400, similar to
AT2G41390					Proteins	unknown protein
					With cDNA	[Arabidopsis thaliana]
					Support
AT5G62800	165	647	8770	6241	Protein	seven in absentia (SINA)
					Destination &	family protein
					Storage
AT1G68380	391	644	10065	5196	Unclassified-	similar to unknown
					Proteins	protein [Arabidopsis
					With cDNA	thaliana]
					Support	(TAIR:AT1G68390.1)
AT4G34520		872	13764	7891	Metabolism	FAE1 (FATTY ACID
						ELONGATION1);
						acyltransferase

PMG genes (ref5_PMG)

AT2G13230

243

Transposon

AT5G65070		170	290	Transcription	AGL69, AT5G65070.1,
					F15O5.3, F15O5_3,
					FCL4, MADS
					AFFECTING
					FLOWERING 4, MAF4
AT1G28640	116	611	872	Metabolism	GDSL-motif lipase,
					putative
AT3G44830	167	746	1463	Metabolism	lecithin:cholesterol
					acyltransferase family
					protein/LACT family
					protein
AT5G27160		955	2127	Unclassified-	similar to unknown
				Proteins	protein [Arabidopsis
				With NO	thaliana]
				cDNA	(TAIR:AT4G07520.1)
				Support
AT2G47120		2135	2508	Metabolism	short-chain
					dehydrogenase/reductase
					(SDR) family protein
AT5G04380		1613	3626	Secondary	S-adenosyl-L-
				Metabolism	methionine:carboxyl
					methyltransferase family
					protein

AT2G05580

1854

4694

Pseudogene

AT2G19320		2711	6063	Unclassified-	unknown protein
				Proteins
				With cDNA
				Support
AT1G80090		4279	9624	Intracellular	CBS domain-containing
				Traffic	protein
AT1G29680		7245	14695	Unclassified-	similar to unknown
				Proteins	protein [Arabidopsis
				With cDNA	thaliana]
				Support	(TAIR:AT5G45690.1)
AT5G55240		7153	17877	Metabolism	caleosin-related family
					protein/embryo-specific
					protein, putative
AT3G60730		11623	17970	Cell	pectinesterase family
				Structure	protein
AT4G10020		8315	18624	Metabolism	short-chain
					dehydrogenase/reductase
					(SDR) family protein
AT1G65090	1463	16059	21943	Unclassified-	similar to unknown
				Proteins	protein [Arabidopsis
				With cDNA	thaliana]
				Support	(TAIR:AT5G36100.1)
AT4G31830		17553	22567	Unclassified-	similar to conserved
				Proteins	hypothetical protein
				With cDNA	[Medicago truncatula]
				Support	(GB:ABE93904.1)
AT1G47540	2019	22709	23291	Disease &	trypsin inhibitor,
				Defense	putative
AT2G33520		8853	24230	Unclassified-	similar to proline-rich
				Proteins	family protein
				With	[Arabidopsis thaliana]
				Unknown	(TAIR:AT1G12810.1)
				Function
AT1G17810		22927	36488	Transporter	BETA-TIP (BETA-
					TONOPLAST
					INTRINSIC PROTEIN);
					water channel
AT3G54940	932	23046	39824	Protein	cysteine proteinase,
				Destination &	putative
				Storage
AT2G15010		23354	41533	Disease &	thionin, putative
				Defense
AT4G26740		25242	42155	Unclassified-	ATS1 (ARABIDOPSIS
				Proteins	THALIANA SEED
				With	GENE 1); calcium ion
				Unknown	binding
				Function
AT3G01570	863	45006	56213	Metabolism	glycine-rich protein/
					oleosin
AT1G48130		33289	57281	Disease &	ATPER1 (Arabidopsis
				Defense	thaliana 1-cysteine
					peroxiredoxin 1);
					antioxidant
AT3G27660	814	50089	60589	Protein	OLEO4 (OLEOSIN4)
				Destination &
				Storage
AT5G40420	1165	43377	61168	Protein	OLEO2 (OLEOSIN 2)
				Destination &
				Storage
AT1G73190		30814	61180	Intracellular	ALPHA-TIP/TIP3;1
				Traffic	(ALPHA-TONOPLAST
					INTRINSIC PROTEIN);
					water channel
AT1G03890		46026	63059	Protein	cupin family protein
				Destination &
				Storage
AT1G04560		44729	65571	Disease &	AWPM-19-like
				Defense	membrane family
					protein
AT1G05510		28938	67087	Unclassified-	similar to unknown
				Proteins	protein [Arabidopsis
				With cDNA	thaliana]
				Support	(TAIR:AT2G31985.1)
AT2G27380	1542	33222	67621	Cell	ATEPR1 (Arabidopsis
				Structure	thaliana extensin
					proline-rich 1)
AT4G25140	440	58084	78774	Protein	OLEO1 (OLEOSIN1)
				Destination &
				Storage
AT4G27160		64367	78804	Protein	2S seed storage protein 3/
				Destination &	2S albumin storage
				Storage	protein/NWMU2-2S
					albumin 3
AT1G03880		96008	119281	Protein	CRU2 (CRUCIFERIN
				Destination &	2); nutrient reservoir
				Storage

* Blank cells indicate no gene expression in that seed stage [consensus detection call of “AA”, as defined in Le et al. (2010)].
Pre-defined gene expression profiles used to generate data are listed in Table 9.
Abbreviations are as follows: 24H, 24-h post-pollination seed; GLOB, globular-stage seed; COT, cotyledon-stage seed; MG, mature-green-stage seed; PMG, postmature-green-stage seed;

To further narrow down the list of suitable promoters, the following criteria were used: (1) genes were selected that exhibited different temporal profiles, i.e. were highest expressed in a particular seed development stage; (2) genes with medium and high expression levels were chosen and genes with low expression levels were omitted; and (3) preference was given to genes whose function was established. These criteria resulted in the selection of 17 genes, three of which appear to encode isoenzymes due to their high sequence homology (Table 11). Use of the promoters from these genes may lead to seeds with high PHB content and high germination/survival. One skilled in the art will recognize that other suitable promoters may be identified by modifying the predefined search profiles described in Table 9.

TABLE 11

Genes with candidate promoters for high PHB production in
seeds that have high germination and survival

AGI ID	GLOB	COT	MG	PMG	Descriptions

AT5G46820;	3,108	1,072			[AT5G46820, similar
AT5G46810					to unknown protein
					[Arabidopsis thaliana]
					(TAIR:AT5G46810.1);
					similar to hypothetical
					protein 25.t00048
					[Brassica oleracea]
					(GB:ABD64955.1);
					contains InterPro
					domain Protein of
					unknown function
					DUF239, plant;
					(InterPro:
					IPR004314)];[AT5
AT5G09490	1,019	438			40S ribosomal protein
					S15 (RPS15B)
AT2G32370	1,208	2,373			homeobox-leucine
					zipper family protein/
					lipid-binding START
					domain-containing
					protein
AT5G07260	908	1,564	472		homeobox protein-
					related
AT1G16980	349	441			ATTPS2
					(Arabidopsis
					thaliana
					trehalose-
					phosphatase/
					synthase 2);
					transferase,
					transferring
					glycosyl groups
AT4G34520		872	13,764	7,891	FAE1 (FATTY ACID
					ELONGATION1);
					acyltransferase
AT2G41400;			6,470	3,905	[AT2G41400, similar
					to unknown protein
					[Arabidopsis thaliana]
AT2G41390					(TAIR:AT2G41390.1)];
					[AT2G41390, similar to
					unknown protein
					[Arabidopsis thaliana]
					(TAIR:AT2G41400.1)]
AT3G04190;			1,503	613	[AT3G04190, germin-
AT3G04180					like protein,
					putative];[AT3G04180,
					germin-like
					protein, putative]
AT1G03880			96,008	119,281	CRUZ (CRUCIFERIN
					2); nutrient reservoir
AT4G27160			64,367	78,804	2S seed storage protein
					3/2S albumin storage
					protein/NWMU2-2S
					albumin 3
AT4G25140		440	58,084	78,774	OLEO1 (OLEOSIN 1)
AT5G40420		1,165	43,377	61,168	OLEO2 (OLEOSIN 2)
AT3G27660		814	50,089	60,589	OLEO4 (OLEOSIN 4)
AT5G04380			1,613	3,626	S-adenosyl-L-
					methionine:carboxyl
					methyltransferase
					family protein

*Numbers in bold indicate the peak expression values of a particular gene in the specified seed development stage. Two AGI ID numbers indicate highly homologous proteins.

Example 10 Increasing Flux through the Calvin Cycle: Design and Construction of Transformation Vectors Expressing a Gene Encoding FBPase/SBPase with Genes Encoding the PHB Biosynthetic Enzymes in Oilseeds

Since expression of a gene encoding the FBPase/SBPase gene from Synechococcus elongatus PCC 7942 (Miyagawa, Y., 2001, Nat Biotechnol, 19, 965-9) and a SBPase cDNA from Arabidopsis (Raines, 2003, Photosynthesis Research, 75, 1-10; Lefebvre et al., 2005, Plant Physiol. 138, 451-460) have previously been shown to enhance photosynthesis and plant growth when expressed in tobacco, insertion of an expression cassette for this gene into plasmid pMBXS490 was performed to see if the health and survival rate of high PHB producing seedlings could be improved. Transformation vectors pMBXS407 and pMBXS408 were prepared that contain the expression cassettes for plastid targeted PHB enzymes from plasmid pMBXS490 and an additional cassette for expression of a FBPase/SBPase gene under the control of the 355 promoter from the cauliflower mosaic virus. Two different sequences for FBPase/SBPase gene from Synechococcus elongatus PCC 7942 are listed in the NCBI database, accession numbers D83512 and CP000100. These two sequences differ at amino acids145 to 148 and at their C-terminus (FIG. 6). Transformation vectors pMBXS407 and pMBXS408 were constructed in which the FBPase/SBPase genes were fused at the 5′ end to a DNA sequence encoding a signal peptide of the small subunit of pea and the first 24 amino acids of the mature protein [Cashmore, A. R. (1983). Nuclear Genes Encoding the Small Subunit of Ribulose-1,5-Bisphosphate Carboxylase. Genetic Engineering of Plants. T. Kosuge, Meredith, C. P. & Hollaender, A. New York, Plenum: 29-38] allowing transport of the proteins into the plastids. Transformation vector pMBXS407 contains a gene encoding a FBPase/SBPase with 100% homology to the FBPase/SBPase protein from Synechococcus elongatus PCC 7942 listed in accession CP000100. Transformation vector pMBXS408 contains a gene encoding a FBPase/SBPase with 100% homology to the FBPase/SBPase protein from Synechococcus elongatus PCC 7942 listed in accession D83512. Even though this gene is listed in accession D83512 as a fructose-1,6-bisphosphatase-I gene, the presence of both FBPase and SBPase activities in the encoded protein has been verified enzymatically (Tamoi, M., et al., 1996, Archives of Biochemistry and Biophysics, 334, 27-36). Transformation vectors pMBXS407 and pMBXS408 were transformed into Camelina and T1 seeds were isolated based on DsRed expression. T1 lines were further propagated and second generation (T2) transgenic seeds were produced. The highest PHB producing lines (i.e. greater than 10% PHB) were generated by germination of seeds in tissue culture medium containing 2% sucrose. The base tissue culture medium was ½×MS agar medium made with Murashige and Skoog medium mixture [Caisson Labs]. Further propagation yielded T3 transgenic seeds that produced PHB at levels up to 13% of the seed weight. Select lines were used in germination trials under controlled greenhouse conditions (Table 12). In general, seedlings generated from the pMBXS407 transformations possessed healthier seedlings and with greater survival rates than seedlings generated from pMBXS408 or pMBXS490 transformations. During the initial stages of growth, transgenic seedlings from the pMBXS407 transformation showed significant increases in growth and biomass production when compared to transgenic seedlings transformed with pMBXS408 and pMBXS490 transformed plants. This increased growth and biomass production persisted through growth of the plants to maturity. The change in shoot biomass in the transgenic plants that may be due to overexpression of the FBPase/SBPase gene in pMBXS407 was correlated to both an increase in stem diameter and leaf surface area.

TABLE 12

PHB content and % survival of T3
linestransformed with construct pMBXS497

	PHB
	Content (%	% survival	10
	PHB in	to 11 days after
Line	Seeds)	planting in soil*

407A-9.9-30	10.45	0
8-32	9	55
8-39	8.5	65
8-23	8	70
8-25	7	95
8-36	7	45
78-37	6	80

*Percent survival test performed by germinating seeds directly in soil in a greenhouse

To test the effects of plastid targeted, seed specific expression of FBPase/SBPase on PHB production, transformation vector pMBXS511 was prepared. This vector contains the PHB gene and DsRed expression cassettes in pMBXS490 and an additional cassette for expression of the Synechococcus elongatus PCC 7942 FBPase/SBPase gene listed in accession gb|CP000100.1 under the control of the seed specific oleosin promoter. In pMBXS511, the plastid targeting sequence from pea including the first 24 amino acids of the mature protein is attached to the 5′ end of the FBPase/SBPase to direct the import of the protein into the plastids.

Vector: pMBXS490

(SEQ ID NO: 1)

1	GGGGATCCGT ACGTAAGTAC GTACTCAAAA TGCCAACAAA
	TAAAAAAAAA

51	GTTGCTTTAA TAATGCCAAA ACAAATTAAT AAAACACTTA
	CAACACCGGA

101	TTTTTTTTAA TTAAAATGTG CCATTTAGGA TAAATAGTTA
	ATATTTTTAA

151	TAATTATTTA AAAAGCCGTA TCTACTAAAA TGATTTTTAT
	TTGGTTGAAA

201	ATATTAATAT GTTTAAATCA ACACAATCTA TCAAAATTAA
	ACTAAAAAAA

251	AAATAAGTGT ACGTGGTTAA CATTAGTACA GTAATATAAG
	AGGAAAATGA

301	GAAATTAAGA AATTGAAAGC GAGTCTAATT TTTAAATTAT
	GAACCTGCAT

351	ATATAAAAGG AAAGAAAGAA TCCAGGAAGA AAAGAAATGA
	AACCATGCAT

401	GGTCCCCTCG TCATCACGAG TTTCTGCCAT TTGCAATAGA
	AACACTGAAA

451	CACCTTTCTC TTTGTCACTT AATTGAGATG CCGAAGCCAC
	CTCACACCAT

501	GAACTTCATG AGGTGTAGCA CCCAAGGCTT CCATAGCCAT
	GCATACTGAA

551	GAATGTCTCA AGCTCAGCAC CCTACTTCTG TGACGTGTCC
	CTCATTCACC

601	TTCCTCTCTT CCCTATAAAT AACCACGCCT CAGGTTCTCC
	GCTTCACAAC

651	TCAAACATTC TCTCCATTGG TCCTTAAACA CTCATCAGTC
	ATCACCGCGG

701	CCGCGGAATT CATGGCTTCT ATGATATCCT CTTCCGCTGT
	GACAACAGTC

751	AGCCGTGCCT CTAGGGGGCA ATCCGCCGCA GTGGCTCCAT
	TCGGCGGCCT

801	CAAATCCATG ACTGGATTCC CAGTGAAGAA GGTCAACACT
	GACATTACTT

851	CCATTACAAG CAATGGTGGA AGAGTAAAGT GCATGCAGGT
	GTGGCCTCCA

901	ATTGGAAAGA AGAAGTTTGA GACTCTTTCC TATTTGCCAC
	CATTGACGAG

951	AGATTCTAGA GTGACTGACG TTGTCATCGT ATCCGCCGCC
	CGCACCGCGG

1001	TCGGCAAGTT TGGCGGCTCG CTGGCCAAGA TCCCGGCACC
	GGAACTGGGT

1051	GCCGTGGTCA TCAAGGCCGC GCTGGAGCGC GCCGGCGTCA
	AGCCGGAGCA

1101	GGTGAGCGAA GTCATCATGG GCCAGGTGCT GACCGCCGGT
	TCGGGCCAGA

1151	ACCCCGCACG CCAGGCCGCG ATCAAGGCCG GCCTGCCGGC
	GATGGTGCCG

1201	GCCATGACCA TCAACAAGGT GTGCGGCTCG GGCCTGAAGG
	CCGTGATGCT

1251	GGCCGCCAAC GCGATCATGG CGGGCGACGC CGAGATCGTG
	GTGGCCGGCG

1301	GCCAGGAAAA CATGAGCGCC GCCCCGCACG TGCTGCCGGG
	CTCGCGCGAT

1351	GGTTTCCGCA TGGGCGATGC CAAGCTGGTC GACACCATGA
	TCGTCGACGG

1401	CCTGTGGGAC GTGTACAACC AGTACCACAT GGGCATCACC
	GCCGAGAACG

1451	TGGCCAAGGA ATACGGCATC ACACGCGAGG CGCAGGATGA
	GTTCGCCGTC

1501	GGCTCGCAGA ACAAGGCCGA AGCCGCGCAG AAGGCCGGCA
	AGTTTGACGA

1551	AGAGATCGTC CCGGTGCTGA TCCCGCAGCG CAAGGGCGAC
	CCGGTGGCCT

1601	TCAAGACCGA CGAGTTCGTG CGCCAGGGCG CCACGCTGGA
	CAGCATGTCC

1651	GGCCTCAAGC CCGCCTTCGA CAAGGCCGGC ACGGTGACCG
	CGGCCAACGC

1701	CTCGGGCCTG AACGACGGCG CCGCCGCGGT GGTGGTGATG
	TCGGCGGCCA

1751	AGGCCAAGGA ACTGGGCCTG ACCCCGCTGG CCACGATCAA
	GAGCTATGCC

1801	AACGCCGGTG TCGATCCCAA GGTGATGGGC ATGGGCCCGG
	TGCCGGCCTC

1851	CAAGCGCGCC CTGTCGCGCG CCGAGTGGAC CCCGCAAGAC
	CTGGACCTGA

1901	TGGAGATCAA CGAGGCCTTT GCCGCGCAGG CGCTGGCGGT
	GCACCAGCAG

1951	ATGGGCTGGG ACACCTCCAA GGTCAATGTG AACGGCGGCG
	CCATCGCCAT

2001	CGGCCACCCG ATCGGCGCGT CGGGCTGCCG TATCCTGGTG
	ACGCTGCTGC

2051	ACGAGATGAA GCGCCGTGAC GCGAAGAAGG GCCTGGCCTC
	GCTGTGCATC

2101	GGCGGCGGCA TGGGCGTGGC GCTGGCAGTC GAGCGCAAAT
	AACTCGAGGC

2151	GGCCGCAGCC CTTTTTGTAT GTGCTACCCC ACTTTTGTCT
	TTTTGGCAAT

2201	AGTGCTAGCA ACCAATAAAT AATAATAATA ATAATGAATA
	AGAAAACAAA

2251	GGCTTTAGCT TGCCTTTTGT TCACTGTAAA ATAATAATGT
	AAGTACTCTC

2301	TATAATGAGT CACGAAACTT TTGCGGGAAT AAAAGGAGAA
	ATTCCAATGA

2351	GTTTTCTGTC AAATCTTCTT TTGTCTCTCT CTCTCTCTCT
	TTTTTTTTTT

2401	TCTTTCTTCT GAGCTTCTTG CAAAACAAAA GGCAAACAAT
	AACGATTGGT

2451	CCAATGATAG TTAGCTTGAT CGATGATATC TTTAGGAAGT
	GTTGGCAGGA

2501	CAGGACATGA TGTAGAAGAC TAAAATTGAA AGTATTGCAG
	ACCCAATAGT

2551	TGAAGATTAA CTTTAAGAAT GAAGACGTCT TATCAGGTTC
	TTCATGACTT

2601	AAGCTTTAAG AGGAGTCCAC CATGGTAGAT CTGACTAGTA
	GAAGGTAATT

2651	ATCCAAGATG TAGCATCAAG AATCCAATGT TTACGGGAAA
	AACTATGGAA

2701	GTATTATGTG AGCTCAGCAA GAAGCAGATC AATATGCGGC
	ACATATGCAA

2751	CCTATGTTCA AAAATGAAGA ATGTACAGAT ACAAGATCCT
	ATACTGCCAG

2801	AATACGAAGA AGAATACGTA GAAATTGAAA AAGAAGAACC
	AGGCGAAGAA

2851	AAGAATCTTG AAGACGTAAG CACTGACGAC AACAATGAAA
	AGAAGAAGAT

2901	AAGGTCGGTG ATTGTGAAAG AGACATAGAG GACACATGTA
	AGGTGGAAAA

2951	TGTAAGGGCG GAAAGTAACC TTATCACAAA GGAATCTTAT
	CCCCCACTAC

3001	TTATCCTTTT ATATTTTTCC GTGTCATTTT TGCCCTTGAG
	TTTTCCTATA

3051	TAAGGAACCA AGTTCGGCAT TTGTGAAAAC AAGAAAAAAT
	TGGTGTAAGC

3101	TATTTTCTTT GAAGTACTGA GGATACAACT TCAGAGAAAT
	TTGTAAGAAA

3151	GTGGATCGAA ACCATGGCCT CCTCCGAGAA CGTCATCACC
	GAGTTCATGC

3201	GCTTCAAGGT GCGCATGGAG GGCACCGTGA ACGGCCACGA
	GTTCGAGATC

3251	GAGGGCGAGG GCGAGGGCCG CCCCTACGAG GGCCACAACA
	CCGTGAAGCT

3301	GAAGGTGACC AAGGGCGGCC CCCTGCCCTT CGCCTGGGAC
	ATCCTGTCCC

3351	CCCAGTTCCA GTACGGCTCC AAGGTGTACG TGAAGCACCC
	CGCCGACATC

3401	CCCGACTACA AGAAGCTGTC CTTCCCCGAG GGCTTCAAGT
	GGGAGCGCGT

3451	GATGAACTTC GAGGACGGCG GCGTGGCGAC CGTGACCCAG
	GACTCCTCCC

3501	TGCAGGACGG CTGCTTCATC TACAAGGTGA AGTTCATCGG
	CGTGAACTTC

3551	CCCTCCGACG GCCCCGTGAT GCAGAAGAAG ACCATGGGCT
	GGGAGGCCTC

3601	CACCGAGCGC CTGTACCCCC GCGACGGCGT GCTGAAGGGC
	GAGACCCACA

3651	AGGCCCTGAA GCTGAAGGAC GGCGGCCACT ACCTGGTGGA
	GTTCAAGTCC

3701	ATCTACATGG CCAAGAAGCC CGTGCAGCTG CCCGGCTACT
	ACTACGTGGA

3751	CGCCAAGCTG GACATCACCT CCCACAACGA GGACTACACC
	ATCGTGGAGC

3801	AGTACGAGCG CACCGAGGGC CGCCACCACC TGTTCCTGGT
	ACCAATGAGC

3851	TCTGTCCAAC AGTCTCAGGG TTAATGTCTA TGTATCTTAA
	ATAATGTTGT

3901	CGGCGATCGT TCAAACATTT GGCAATAAAG TTTCTTAAGA
	TTGAATCCTG

3951	TTGCCGGTCT TGCGATGATT ATCATATAAT TTCTGTTGAA
	TTACGTTAAG

4001	CATGTAATAA TTAACATGTA ATGCATGACG TTATTTATGA
	GATGGGTTTT

4051	TATGATTAGA GTCCCGCAAT TATACATTTA ATACGCGATA
	GAAAACAAAA

4101	TATAGCGCGC AAACTAGGAT AAATTATCGC GCGCGGTGTC
	ATCTATGTTA

4151	CTAGATCGGG AATTAAACTA TCAGTGTTTG ACAGGATATA
	TTGGCGGGTA

4201	AACCTAAGAG AAAAGAGCGT TTATTAGAAT AACGGATATT
	TAAAAGGGCG

4251	TGAAAAGGTT TATCCGTTCG TCCATTTGTA TGTGCATGCC
	AACCACAGGG

4301	TTCCCCTCGG GATCAAAGTA CTTTGATCCA ACCCCTCCGC
	TGCTATAGTG

4351	CAGTCGGCTT CTGACGTTCA GTGCAGCCGT CTTCTGAAAA
	CGACATGTCG

4401	CACAAGTCCT AAGTTACGCG ACAGGCTGCC GCCCTGCCCT
	TTTCCTGGCG

4451	TTTTCTTGTC GCGTGTTTTA GTCGCATAAA GTAGAATACT
	TGCGACTAGA

4501	ACCGGAGACA TTACGCCATG AACAAGAGCG CCGCCGCTGG
	CCTGCTGGGC

4551	TATGCCCGCG TCAGCACCGA CGACCAGGAC TTGACCAACC
	AACGGGCCGA

4601	ACTGCACGCG GCCGGCTGCA CCAAGCTGTT TTCCGAGAAG
	ATCACCGGCA

4651	CCAGGCGCGA CCGCCCGGAG CTGGCCAGGA TGCTTGACCA
	CCTACGCCCT

4701	GGCGACGTTG TGACAGTGAC CAGGCTAGAC CGCCTGGCCC
	GCAGCACCCG

4751	CGACCTACTG GACATTGCCG AGCGCATCCA GGAGGCCGGC
	GCGGGCCTGC

4801	GTAGCCTGGC AGAGCCGTGG GCCGACACCA CCACGCCGGC
	CGGCCGCATG

4851	GTGTTGACCG TGTTCGCCGG CATTGCCGAG TTCGAGCGTT
	CCCTAATCAT

4901	CGACCGCACC CGGAGCGGGC GCGAGGCCGC CAAGGCCCGA
	GGCGTGAAGT

4951	TTGGCCCCCG CCCTACCCTC ACCCCGGCAC AGATCGCGCA
	CGCCCGCGAG

5001	CTGATCGACC AGGAAGGCCG CACCGTGAAA GAGGCGGCTG
	CACTGCTTGG

5051	CGTGCATCGC TCGACCCTGT ACCGCGCACT TGAGCGCAGC
	GAGGAAGTGA

5101	CGCCCACCGA GGCCAGGCGG CGCGGTGCCT TCCGTGAGGA
	CGCATTGACC

5151	GAGGCCGACG CCCTGGCGGC CGCCGAGAAT GAACGCCAAG
	AGGAACAAGC

5201	ATGAAACCGC ACCAGGACGG CCAGGACGAA CCGTTTTTCA
	TTACCGAAGA

5251	GATCGAGGCG GAGATGATCG CGGCCGGGTA CGTGTTCGAG
	CCGCCCGCGC

5301	ACGTCTCAAC CGTGCAGCTG CATGAAATCC TGGCCGGTTT
	GTCTGATGCC

5351	AAGCTGGCGG CCTGGCCGGC CAGCTTGGCC GCTGAAGAAA
	CCGAGCGCCG

5401	CCGTCTAAAA AGGTGATGTG TATTTGAGTA AAACAGCTTG
	CGTCATGCGG

5451	TCGCTGCGTA TATGATGCGA TGAGTAAATA AACAAATACG
	CAAGGGGAAC

5501	GCATGAAGGT TATCGCTGTA CTTAACCAGA AAGGCGGGTC
	AGGCAAGACG

5551	ACCATCGCAA CCCATCTAGC CCGCGCCCTG CAACTCGCCG
	GGGCCGATGT

5601	TCTGTTAGTC GATTCCGATC CCCAGGGCAG TGCCCGCGAT
	TGGGCGGCCG

5651	TGCGGGAAGA TCAACCGCTA ACCGTTGTCG GCATCGACCG
	CCCGACGATT

5701	GACCGCGACG TGAAGGCCAT CGGCCGGCGC GACTTCGTAG
	TGATCGACGG

5751	AGCGCCCCAG GCGGCGGACT TGGCTGTGTC CGCGATCAAG
	GCAGCCGACT

5801	TCGTGCTGAT TCCGGTGCAG CCAAGCCCTT ACGACATATG
	GGCCACCGCC

5851	GACCTGGTGG AGCTGGTTAA GCAGCGCATT GAGGTCACGG
	ATGGAAGGCT

5901	ACAAGCGGCC TTTGTCGTGT CGCGGGCGAT CAAAGGCACG
	CGCATCGGCG

5951	GTGAGGTTGC CGAGGCGCTG GCCGGGTACG AGCTGCCCAT
	TCTTGAGTCC

6001	CGTATCACGC AGCGCGTGAG CTACCCAGGC ACTGCCGCCG
	CCGGCACAAC

6051	CGTTCTTGAA TCAGAACCCG AGGGCGACGC TGCCCGCGAG
	GTCCAGGCGC

6101	TGGCCGCTGA AATTAAATCA AAACTCATTT GAGTTAATGA
	GGTAAAGAGA

6151	AAATGAGCAA AAGCACAAAC ACGCTAAGTG CCGGCCGTCC
	GAGCGCACGC

6201	AGCAGCAAGG CTGCAACGTT GGCCAGCCTG GCAGACACGC
	CAGCCATGAA

6251	GCGGGTCAAC TTTCAGTTGC CGGCGGAGGA TCACACCAAG
	CTGAAGATGT

6301	ACGCGGTACG CCAAGGCAAG ACCATTACCG AGCTGCTATC
	TGAATACATC

6351	GCGCAGCTAC CAGAGTAAAT GAGCAAATGA ATAAATGAGT
	AGATGAATTT

6401	TAGCGGCTAA AGGAGGCGGC ATGGAAAATC AAGAACAACC
	AGGCACCGAC

6451	GCCGTGGAAT GCCCCATGTG TGGAGGAACG GGCGGTTGGC
	CAGGCGTAAG

6501	CGGCTGGGTT GTCTGCCGGC CCTGCAATGG CACTGGAACC
	CCCAAGCCCG

6551	AGGAATCGGC GTGACGGTCG CAAACCATCC GGCCCGGTAC
	AAATCGGCGC

6601	GGCGCTGGGT GATGACCTGG TGGAGAAGTT GAAGGCCGCG
	CAGGCCGCCC

6651	AGCGGCAACG CATCGAGGCA GAAGCACGCC CCGGTGAATC
	GTGGCAAGCG

6701	GCCGCTGATC GAATCCGCAA AGAATCCCGG CAACCGCCGG
	CAGCCGGTGC

6751	GCCGTCGATT AGGAAGCCGC CCAAGGGCGA CGAGCAACCA
	GATTTTTTCG

6801	TTCCGATGCT CTATGACGTG GGCACCCGCG ATAGTCGCAG
	CATCATGGAC

6851	GTGGCCGTTT TCCGTCTGTC GAAGCGTGAC CGACGAGCTG
	GCGAGGTGAT

6901	CCGCTACGAG CTTCCAGACG GGCACGTAGA GGTTTCCGCA
	GGGCCGGCCG

6951	GCATGGCCAG TGTGTGGGAT TACGACCTGG TACTGATGGC
	GGTTTCCCAT

7001	CTAACCGAAT CCATGAACCG ATACCGGGAA GGGAAGGGAG
	ACAAGCCCGG

7051	CCGCGTGTTC CGTCCACACG TTGCGGACGT ACTCAAGTTC
	TGCCGGCGAG

7101	CCGATGGCGG AAAGCAGAAA GACGACCTGG TAGAAACCTG
	CATTCGGTTA

7151	AACACCACGC ACGTTGCCAT GCAGCGTACG AAGAAGGCCA
	AGAACGGCCG

7201	CCTGGTGACG GTATCCGAGG GTGAAGCCTT GATTAGCCGC
	TACAAGATCG

7251	TAAAGAGCGA AACCGGGCGG CCGGAGTACA TCGAGATCGA
	GCTAGCTGAT

7301	TGGATGTACC GCGAGATCAC AGAAGGCAAG AACCCGGACG
	TGCTGACGGT

7351	TCACCCCGAT TACTTTTTGA TCGATCCCGG CATCGGCCGT
	TTTCTCTACC

7401	GCCTGGCACG CCGCGCCGCA GGCAAGGCAG AAGCCAGATG
	GTTGTTCAAG

7451	ACGATCTACG AACGCAGTGG CAGCGCCGGA GAGTTCAAGA
	AGTTCTGTTT

7501	CACCGTGCGC AAGCTGATCG GGTCAAATGA CCTGCCGGAG
	TACGATTTGA

7551	AGGAGGAGGC GGGGCAGGCT GGCCCGATCC TAGTCATGCG
	CTACCGCAAC

7601	CTGATCGAGG GCGAAGCATC CGCCGGTTCC TAATGTACGG
	AGCAGATGCT

7651	AGGGCAAATT GCCCTAGCAG GGGAAAAAGG TCGAAAAGGT
	CTCTTTCCTG

7701	TGGATAGCAC GTACATTGGG AACCCAAAGC CGTACATTGG
	GAACCGGAAC

7751	CCGTACATTG GGAACCCAAA GCCGTACATT GGGAACCGGT
	CACACATGTA

7801	AGTGACTGAT ATAAAAGAGA AAAAAGGCGA TTTTTCCGCC
	TAAAACTCTT

7851	TAAAACTTAT TAAAACTCTT AAAACCCGCC TGGCCTGTGC
	ATAACTGTCT

7901	GGCCAGCGCA CAGCCGAAGA GCTGCAAAAA GCGCCTACCC
	TTCGGTCGCT

7951	GCGCTCCCTA CGCCCCGCCG CTTCGCGTCG GCCTATCGCG
	GCCGCTGGCC

8001	GCTCAAAAAT GGCTGGCCTA CGGCCAGGCA ATCTACCAGG
	GCGCGGACAA

8051	GCCGCGCCGT CGCCACTCGA CCGCCGGCGC CCACATCAAG
	GCACCCTGCC

8101	TCGCGCGTTT CGGTGATGAC GGTGAAAACC TCTGACACAT
	GCAGCTCCCG

8151	GAGACGGTCA CAGCTTGTCT GTAAGCGGAT GCCGGGAGCA
	GACAAGCCCG

8201	TCAGGGCGCG TCAGCGGGTG TTGGCGGGTG TCGGGGCGCA
	GCCATGACCC

8251	AGTCACGTAG CGATAGCGGA GTGTATACTG GCTTAACTAT
	GCGGCATCAG

8301	AGCAGATTGT ACTGAGAGTG CACCATATGC GGTGTGAAAT
	ACCGCACAGA

8351	TGCGTAAGGA GAAAATACCG CATCAGGCGC TCTTCCGCTT
	CCTCGCTCAC

8401	TGACTCGCTG CGCTCGGTCG TTCGGCTGCG GCGAGCGGTA
	TCAGCTCACT

8451	CAAAGGCGGT AATACGGTTA TCCACAGAAT CAGGGGATAA
	CGCAGGAAAG

8501	AACATGTGAG CAAAAGGCCA GCAAAAGGCC AGGAACCGTA
	AAAAGGCCGC

8551	GTTGCTGGCG TTTTTCCATA GGCTCCGCCC CCCTGACGAG
	CATCACAAAA

8601	ATCGACGCTC AAGTCAGAGG TGGCGAAACC CGACAGGACT
	ATAAAGATAC

8651	CAGGCGTTTC CCCCTGGAAG CTCCCTCGTG CGCTCTCCTG
	TTCCGACCCT

8701	GCCGCTTACC GGATACCTGT CCGCCTTTCT CCCTTCGGGA
	AGCGTGGCGC

8751	TTTCTCATAG CTCACGCTGT AGGTATCTCA GTTCGGTGTA
	GGTCGTTCGC

8801	TCCAAGCTGG GCTGTGTGCA CGAACCCCCC GTTCAGCCCG
	ACCGCTGCGC

8851	CTTATCCGGT AACTATCGTC TTGAGTCCAA CCCGGTAAGA
	CACGACTTAT

8901	CGCCACTGGC AGCAGCCACT GGTAACAGGA TTAGCAGAGC
	GAGGTATGTA

8951	GGCGGTGCTA CAGAGTTCTT GAAGTGGTGG CCTAACTACG
	GCTACACTAG

9001	AAGGACAGTA TTTGGTATCT GCGCTCTGCT GAAGCCAGTT
	ACCTTCGGAA

9051	AAAGAGTTGG TAGCTCTTGA TCCGGCAAAC AAACCACCGC
	TGGTAGCGGT

9101	GGTTTTTTTG TTTGCAAGCA GCAGATTACG CGCAGAAAAA
	AAGGATCTCA

9151	AGAAGATCCT TTGATCTTTT CTACGGGGTC TGACGCTCAG
	TGGAACGAAA

9201	ACTCACGTTA AGGGATTTTG GTCATGCATT CTAGGTACTA
	AAACAATTCA

9251	TCCAGTAAAA TATAATATTT TATTTTCTCC CAATCAGGCT
	TGATCCCCAG

9301	TAAGTCAAAA AATAGCTCGA CATACTGTTC TTCCCCGATA
	TCCTCCCTGA

9351	TCGACCGGAC GCAGAAGGCA ATGTCATACC ACTTGTCCGC
	CCTGCCGCTT

9401	CTCCCAAGAT CAATAAAGCC ACTTACTTTG CCATCTTTCA
	CAAAGATGTT

9451	GCTGTCTCCC AGGTCGCCGT GGGAAAAGAC AAGTTCCTCT
	TCGGGCTTTT

9501	CCGTCTTTAA AAAATCATAC AGCTCGCGCG GATCTTTAAA
	TGGAGTGTCT

9551	TCTTCCCAGT TTTCGCAATC CACATCGGCC AGATCGTTAT
	TCAGTAAGTA

9601	ATCCAATTCG GCTAAGCGGC TGTCTAAGCT ATTCGTATAG
	GGACAATCCG

9651	ATATGTCGAT GGAGTGAAAG AGCCTGATGC ACTCCGCATA
	CAGCTCGATA

9701	ATCTTTTCAG GGCTTTGTTC ATCTTCATAC TCTTCCGAGC
	AAAGGACGCC

9751	ATCGGCCTCA CTCATGAGCA GATTGCTCCA GCCATCATGC
	CGTTCAAAGT

9801	GCAGGACCTT TGGAACAGGC AGCTTTCCTT CCAGCCATAG
	CATCATGTCC

9851	TTTTCCCGTT CCACATCATA GGTGGTCCCT TTATACCGGC
	TGTCCGTCAT

9901	TTTTAAATAT AGGTTTTCAT TTTCTCCCAC CAGCTTATAT
	ACCTTAGCAG

9951	GAGACATTCC TTCCGTATCT TTTACGCAGC GGTATTTTTC
	GATCAGTTTT

10001	TTCAATTCCG GTGATATTCT CATTTTAGCC ATTTATTATT
	TCCTTCCTCT

10051	TTTCTACAGT ATTTAAAGAT ACCCCAAGAA GCTAATTATA
	ACAAGACGAA

10101	CTCCAATTCA CTGTTCCTTG CATTCTAAAA CCTTAAATAC
	CAGAAAACAG

10151	CTTTTTCAAA GTTGTTTTCA AAGTTGGCGT ATAACATAGT
	ATCGACGGAG

10201	CCGATTTTGA AACCGCGGTG ATCACAGGCA GCAACGCTCT
	GTCATCGTTA

10251	CAATCAACAT GCTACCCTCC GCGAGATCAT CCGTGTTTCA
	AACCCGGCAG

10301	CTTAGTTGCC GTTCTTCCGA ATAGCATCGG TAACATGAGC
	AAAGTCTGCC

10351	GCCTTACAAC GGCTCTCCCG CTGACGCCGT CCCGGACTGA
	TGGGCTGCCT

10401	GTATCGAGTG GTGATTTTGT GCCGAGCTGC CGGTCGGGGA
	GCTGTTGGCT

10451	GGCTGGTGGC AGGATATATT GTGGTGTAAA CAAATTGACG
	CTTAGACAAC

10501	TTAATAACAC ATTGCGGACG TTTTTAATGT ACTGAATTAA
	CGCCGAATTA

10551	ATTCCTAGGC CACCATGTTG GGCCCGGGGC GCGCCGTACG
	TAGTGTTTAT

10601	CTTTGTTGCT TTTCTGAACA ATTTATTTAC TATGTAAATA
	TATTATCAAT

10651	GTTTAATCTA TTTTAATTTG CACATGAATT TTCATTTTAT
	TTTTACTTTA

10701	CAAAACAAAT AAATATATAT GCAAAAAAAT TTACAAACGA
	TGCACGGGTT

10751	ACAAACTAAT TTCATTAAAT GCTAATGCAG ATTTTGTGAA
	GTAAAACTCC

10801	AATTATGATG AAAAATACCA CCAACACCAC CTGCGAAACT
	GTATCCCAAC

10851	TGTCCTTAAT AAAAATGTTA AAAAGTATAT TATTCTCATT
	TGTCTGTCAT

10901	AATTTATGTA CCCCACTTTA ATTTTTCTGA TGTACTAAAC
	CGAGGGCAAA

10951	CTGAAACCTG TTCCTCATGC AAAGCCCCTA CTCACCATGT
	ATCATGTACG

11001	TGTCATCACC CAACAACTCC ACTTTTGCTA TATAACAACA
	CCCCCGTCAC

11051	ACTCTCCCTC TCTAACACAC ACCCCACTAA CAATTCCTTC
	ACTTGCAGCA

11101	CTGTTGCATC ATCATCTTCA TTGCAAAACC CTAAACTTCA
	CCTTCAACCG

11151	CGGCCGCATG GCTTCTATGA TATCCTCTTC CGCTGTGACA
	ACAGTCAGCC

11201	GTGCCTCTAG GGGGCAATCC GCCGCAGTGG CTCCATTCGG
	CGGCCTCAAA

11251	TCCATGACTG GATTCCCAGT GAAGAAGGTC AACACTGACA
	TTACTTCCAT

11301	TACAAGCAAT GGTGGAAGAG TAAAGTGCAT GCAGGTGTGG
	CCTCCAATTG

11351	GAAAGAAGAA GTTTGAGACT CTTTCCTATT TGCCACCATT
	GACGAGAGAT

11401	TCTAGAGTGA GTAACAAGAA CAACGATGAG CTGCAGTGGC
	AATCCTGGTT

11451	CAGCAAGGCG CCCACCACCG AGGCGAACCC GATGGCCACC
	ATGTTGCAGG

11501	ATATCGGCGT TGCGCTCAAA CCGGAAGCGA TGGAGCAGCT
	GAAAAACGAT

11551	TATCTGCGTG ACTTCACCGC GTTGTGGCAG GATTTTTTGG
	CTGGCAAGGC

11601	GCCAGCCGTC AGCGACCGCC GCTTCAGCTC GGCAGCCTGG
	CAGGGCAATC

11651	CGATGTCGGC CTTCAATGCC GCATCTTACC TGCTCAACGC
	CAAATTCCTC

11701	AGTGCCATGG TGGAGGCGGT GGACACCGCA CCCCAGCAAA
	AGCAGAAAAT

11751	ACGCTTTGCC GTGCAGCAGG TGATTGATGC CATGTCGCCC
	GCGAACTTCC

11801	TCGCCACCAA CCCGGAAGCG CAGCAAAAAC TGATTGAAAC
	CAAGGGCGAG

11851	AGCCTGACGC GTGGCCTGGT CAATATGCTG GGCGATATCA
	ACAAGGGCCA

11901	TATCTCGCTG TCGGACGAAT CGGCCTTTGA AGTGGGCCGC
	AACCTGGCCA

11951	TTACCCCGGG CACCGTGATT TACGAAAATC CGCTGTTCCA
	GCTGATCCAG

12001	TACACGCCGA CCACGCCGAC GGTCAGCCAG CGCCCGCTGT
	TGATGGTGCC

12051	GCCGTGCATC AACAAGTTCT ACATCCTCGA CCTGCAACCG
	GAAAATTCGC

12101	TGGTGCGCTA CGCGGTGGAG CAGGGCAACA CCGTGTTCCT
	GATCTCGTGG

12151	AGCAATCCGG ACAAGTCGCT GGCCGGCACC ACCTGGGACG
	ACTACGTGGA

12201	GCAGGGCGTG ATCGAAGCGA TCCGCATCGT CCAGGACGTC
	AGCGGCCAGG

12251	ACAAGCTGAA CATGTTCGGC TTCTGCGTGG GCGGCACCAT
	CGTTGCCACC

12301	GCACTGGCGG TACTGGCGGC GCGTGGCCAG CACCCGGCGG
	CCAGCCTGAC

12351	CCTGCTGACC ACCTTCCTCG ACTTCAGCGA CACCGGCGTG
	CTCGACGTCT

12401	TCGTCGATGA AACCCAGGTC GCGCTGCGTG AACAGCAATT
	GCGCGATGGC

12451	GGCCTGATGC CGGGCCGTGA CCTGGCCTCG ACCTTCTCGA
	GCCTGCGTCC

12501	GAACGACCTG GTATGGAACT ATGTGCAGTC GAACTACCTC
	AAAGGCAATG

12551	AGCCGGCGGC GTTTGACCTG CTGTTCTGGA ATTCGGACAG
	CACCAATTTG

12601	CCGGGCCCGA TGTTCTGCTG GTACCTGCGC AACACCTACC
	TGGAAAACAG

12651	CCTGAAAGTG CCGGGCAAGC TGACGGTGGC CGGCGAAAAG
	ATCGACCTCG

12701	GCCTGATCGA CGCCCCGGCC TTCATCTACG GTTCGCGCGA
	AGACCACATC

12751	GTGCCGTGGA TGTCGGCGTA CGGTTCGCTC GACATCCTCA
	ACCAGGGCAA

12801	GCCGGGCGCC AACCGCTTCG TGCTGGGCGC GTCCGGCCAT
	ATCGCCGGCG

12851	TGATCAACTC GGTGGCCAAG AACAAGCGCA GCTACTGGAT
	CAACGACGGT

12901	GGCGCCGCCG ATGCCCAGGC CTGGTTCGAT GGCGCGCAGG
	AAGTGCCGGG

12951	CAGCTGGTGG CCGCAATGGG CCGGGTTCCT GACCCAGCAT
	GGCGGCAAGA

13001	AGGTCAAGCC CAAAACCAAG CCCGGCAACG CCCGCTACAC
	CGCGATCGAG

13051	GCGGCGCCCG GCCGTTACGT CAAAGCCAAG GGCTGAGCGG
	CCGCTGAGTA

13101	ATTCTGATAT TAGAGGGAGC ATTAATGTGT TGTTGTGATG
	TGGTTTATAT

13151	GGGGAAATTA AATAAATGAT GTATGTACCT CTTGCCTATG
	TAGGTTTGTG

13201	TGTTTTGTTT TGTTGTCTAG CTTTGGTTAT TAAGTAGTAG
	GGACGTTCGT

13251	TCGTGTCTCA AAAAAAGGGG TACTACCACT CTGTAGTGTA
	TATGGATGCT

13301	GGAAATCAAT GTGTTTTGTA TTTGTTCACC TCCATTGTTG
	AATTCAATGT

13351	CAAATGTGTT TTGCGTTGGT TATGTGTAAA ATTACTATCT
	TTCTCGTCCG

13401	ATGATCAAAG TTTTAAGCAA CAAAACCAAG GGTGAAATTT
	AAACTGTGCT

13451	TTGTTGAAGA TTCTTTTATC ATATTGAAAA TCAAATTACT
	AGCAGCAGAT

13501	TTTACCTAGC ATGAAATTTT ATCAACAGTA CAGCACTCAC
	TAACCAAGTT

13551	CCAAACTAAG ATGCGCCATT AACATCAGCC AATAGGCATT
	TTCAGCAAGG

13601	CGCGCCCGCG CCGATGTATG TGACAACCCT CGGGATTGTT
	GATTTATTTC

13651	AAAACTAAGA GTTTTTGTCT TATTGTTCTC GTCTATTTTG
	GATATCAATC

13701	TTAGTTTTAT ATCTTTTCTA GTTCTCTACG TGTTAAATGT
	TCAACACACT

13751	AGCAATTTGG CCTGCCAGCG TATGGATTAT GGAACTATCA
	AGTCTGTGAC

13801	GCGCCGTACG TAGTGTTTAT CTTTGTTGCT TTTCTGAACA
	ATTTATTTAC

13851	TATGTAAATA TATTATCAAT GTTTAATCTA TTTTAATTTG
	CACATGAATT

13901	TTCATTTTAT TTTTACTTTA CAAAACAAAT AAATATATAT
	GCAAAAAAAT

13951	TTACAAACGA TGCACGGGTT ACAAACTAAT TTCATTAAAT
	GCTAATGCAG

14001	ATTTTGTGAA GTAAAACTCC AATTATGATG AAAAATACCA
	CCAACACCAC

14051	CTGCGAAACT GTATCCCAAC TGTCCTTAAT AAAAATGTTA
	AAAAGTATAT

14101	TATTCTCATT TGTCTGTCAT AATTTATGTA CCCCACTTTA
	ATTTTTCTGA

14151	TGTACTAAAC CGAGGGCAAA CTGAAACCTG TTCCTCATGC
	AAAGCCCCTA

14201	CTCACCATGT ATCATGTACG TGTCATCACC CAACAACTCC
	ACTTTTGCTA

14251	TATAACAACA CCCCCGTCAC ACTCTCCCTC TCTAACACAC
	ACCCCACTAA

14301	CAATTCCTTC ACTTGCAGCA CTGTTGCATC ATCATCTTCA
	TTGCAAAACC

14351	CTAAACTTCA CCTTCAACCG CGGCCGCATG GCTTCTATGA
	TATCCTCTTC

14401	CGCTGTGACA ACAGTCAGCC GTGCCTCTAG GGGGCAATCC
	GCCGCAGTGG

14451	CTCCATTCGG CGGCCTCAAA TCCATGACTG GATTCCCAGT
	GAAGAAGGTC

14501	AACACTGACA TTACTTCCAT TACAAGCAAT GGTGGAAGAG
	TAAAGTGCAT

14551	GCAGGTGTGG CCTCCAATTG GAAAGAAGAA GTTTGAGACT
	CTTTCCTATT

14601	TGCCACCATT GACGAGAGAT TCTAGAGTGA CTCAGCGCAT
	TGCGTATGTG

14651	ACCGGCGGCA TGGGTGGTAT CGGAACCGCC ATTTGCCAGC
	GGCTGGCCAA

14701	GGATGGCTTT CGTGTGGTGG CCGGTTGCGG CCCCAACTCG
	CCGCGCCGCG

14751	AAAAGTGGCT GGAGCAGCAG AAGGCCCTGG GCTTCGATTT
	CATTGCCTCG

14801	GAAGGCAATG TGGCTGACTG GGACTCGACC AAGACCGCAT
	TCGACAAGGT

14851	CAAGTCCGAG GTCGGCGAGG TTGATGTGCT GATCAACAAC
	GCCGGTATCA

14901	CCCGCGACGT GGTGTTCCGC AAGATGACCC GCGCCGACTG
	GGATGCGGTG

14951	ATCGACACCA ACCTGACCTC GCTGTTCAAC GTCACCAAGC
	AGGTGATCGA

15001	CGGCATGGCC GACCGTGGCT GGGGCCGCAT CGTCAACATC
	TCGTCGATGA

15051	ACGGGCAGAA GGGCCAGTTC GGCCAGACCA ACTACTCCAC
	CGCCAAGGCC

15101	GGCCTGCATG GCTTCACCAT GGCACTGGCG CAGGAAGTGG
	CGACCAAGGG

15151	CGTGACCGTC AACACGGTCT CTCCGGGCTA TATCGCCACC
	GACATGGTCA

15201	AGGCGATCCG CCAGGACGTG CTCGACAAGA TCGTCGCGAC
	GATCCCGGTC

15251	AAGCGCCTGG GCCTGCCGGA AGAGATCGCC TCGATCTGCG
	CCTGGTTGTC

15301	GTCGGAGGAG TCCGGTTTCT CGACCGGCGC CGACTTCTCG
	CTCAACGGCG

15351	GCCTGCATAT GGGCTGAGCG GCCGCTGAGT AATTCTGATA
	TTAGAGGGAG

15401	CATTAATGTG TTGTTGTGAT GTGGTTTATA TGGGGAAATT
	AAATAAATGA

15451	TGTATGTACC TCTTGCCTAT GTAGGTTTGT GTGTTTTGTT
	TTGTTGTCTA

15501	GCTTTGGTTA TTAAGTAGTA GGGACGTTCG TTCGTGTCTC
	AAAAAAAGGG

15551	GTACTACCAC TCTGTAGTGT ATATGGATGC TGGAAATCAA
	TGTGTTTTGT

15601	ATTTGTTCAC CTCCATTGTT GAATTCAATG TCAAATGTGT
	TTTGCGTTGG

15651	TTATGTGTAA AATTACTATC TTTCTCGTCC GATGATCAAA
	GTTTTAAGCA

15701	ACAAAACCAA GGGTGAAATT TAAACTGTGC TTTGTTGAAG
	ATTCTTTTAT

15751	CATATTGAAA ATCAAATTAC TAGCAGCAGA TTTTACCTAG
	CATGAAATTT

15801	TATCAACAGT ACAGCACTCA CTAACCAAGT TCCAAACTAA
	GATGCGCCAT

15851	TAACATCAGC CAATAGGCAT TTTCAGCAAG GCGCGTAA

pMBXS364

(SEQ ID NO: 2)

1	CATGCCAACC ACAGGGTTCC CCTCGGGATC AAAGTACTTT
	GATCCAACCC

51	CTCCGCTGCT ATAGTGCAGT CGGCTTCTGA CGTTCAGTGC
	AGCCGTCTTC

101	TGAAAACGAC ATGTCGCACA AGTCCTAAGT TACGCGACAG
	GCTGCCGCCC

151	TGCCCTTTTC CTGGCGTTTT CTTGTCGCGT GTTTTAGTCG
	CATAAAGTAG

201	AATACTTGCG ACTAGAACCG GAGACATTAC GCCATGAACA
	AGAGCGCCGC

251	CGCTGGCCTG CTGGGCTATG CCCGCGTCAG CACCGACGAC
	CAGGACTTGA

301	CCAACCAACG GGCCGAACTG CACGCGGCCG GCTGCACCAA
	GCTGTTTTCC

351	GAGAAGATCA CCGGCACCAG GCGCGACCGC CCGGAGCTGG
	CCAGGATGCT

401	TGACCACCTA CGCCCTGGCG ACGTTGTGAC AGTGACCAGG
	CTAGACCGCC

451	TGGCCCGCAG CACCCGCGAC CTACTGGACA TTGCCGAGCG
	CATCCAGGAG

501	GCCGGCGCGG GCCTGCGTAG CCTGGCAGAG CCGTGGGCCG
	ACACCACCAC

551	GCCGGCCGGC CGCATGGTGT TGACCGTGTT CGCCGGCATT
	GCCGAGTTCG

601	AGCGTTCCCT AATCATCGAC CGCACCCGGA GCGGGCGCGA
	GGCCGCCAAG

651	GCCCGAGGCG TGAAGTTTGG CCCCCGCCCT ACCCTCACCC
	CGGCACAGAT

701	CGCGCACGCC CGCGAGCTGA TCGACCAGGA AGGCCGCACC
	GTGAAAGAGG

751	CGGCTGCACT GCTTGGCGTG CATCGCTCGA CCCTGTACCG
	CGCACTTGAG

801	CGCAGCGAGG AAGTGACGCC CACCGAGGCC AGGCGGCGCG
	GTGCCTTCCG

851	TGAGGACGCA TTGACCGAGG CCGACGCCCT GGCGGCCGCC
	GAGAATGAAC

901	GCCAAGAGGA ACAAGCATGA AACCGCACCA GGACGGCCAG
	GACGAACCGT

951	TTTTCATTAC CGAAGAGATC GAGGCGGAGA TGATCGCGGC
	CGGGTACGTG

1001	TTCGAGCCGC CCGCGCACGT CTCAACCGTG CGGCTGCATG
	AAATCCTGGC

1051	CGGTTTGTCT GATGCCAAGC TGGCGGCCTG GCCGGCCAGC
	TTGGCCGCTG

1101	AAGAAACCGA GCGCCGCCGT CTAAAAAGGT GATGTGTATT
	TGAGTAAAAC

1151	AGCTTGCGTC ATGCGGTCGC TGCGTATATG ATGCGATGAG
	TAAATAAACA

1201	AATACGCAAG GGGAACGCAT GAAGGTTATC GCTGTACTTA
	ACCAGAAAGG

1251	CGGGTCAGGC AAGACGACCA TCGCAACCCA TCTAGCCCGC
	GCCCTGCAAC

1301	TCGCCGGGGC CGATGTTCTG TTAGTCGATT CCGATCCCCA
	GGGCAGTGCC

1351	CGCGATTGGG CGGCCGTGCG GGAAGATCAA CCGCTAACCG
	TTGTCGGCAT

1401	CGACCGCCCG ACGATTGACC GCGACGTGAA GGCCATCGGC
	CGGCGCGACT

1451	TCGTAGTGAT CGACGGAGCG CCCCAGGCGG CGGACTTGGC
	TGTGTCCGCG

1501	ATCAAGGCAG CCGACTTCGT GCTGATTCCG GTGCAGCCAA
	GCCCTTACGA

1551	CATATGGGCC ACCGCCGACC TGGTGGAGCT GGTTAAGCAG
	CGCATTGAGG

1601	TCACGGATGG AAGGCTACAA GCGGCCTTTG TCGTGTCGCG
	GGCGATCAAA

1651	GGCACGCGCA TCGGCGGTGA GGTTGCCGAG GCGCTGGCCG
	GGTACGAGCT

1701	GCCCATTCTT GAGTCCCGTA TCACGCAGCG CGTGAGCTAC
	CCAGGCACTG

1751	CCGCCGCCGG CACAACCGTT CTTGAATCAG AACCCGAGGG
	CGACGCTGCC

1801	CGCGAGGTCC AGGCGCTGGC CGCTGAAATT AAATCAAAAC
	TCATTTGAGT

1851	TAATGAGGTA AAGAGAAAAT GAGCAAAAGC ACAAACACGC
	TAAGTGCCGG

1901	CCGTCCGAGC GCACGCAGCA GCAAGGCTGC AACGTTGGCC
	AGCCTGGCAG

1951	ACACGCCAGC CATGAAGCGG GTCAACTTTC AGTTGCCGGC
	GGAGGATCAC

2001	ACCAAGCTGA AGATGTACGC GGTACGCCAA GGCAAGACCA
	TTACCGAGCT

2051	GCTATCTGAA TACATCGCGC AGCTACCAGA GTAAATGAGC
	AAATGAATAA

2101	ATGAGTAGAT GAATTTTAGC GGCTAAAGGA GGCGGCATGG
	AAAATCAAGA

2151	ACAACCAGGC ACCGACGCCG TGGAATGCCC CATGTGTGGA
	GGAACGGGCG

2201	GTTGGCCAGG CGTAAGCGGC TGGGTTGTCT GCCGGCCCTG
	CAATGGCACT

2251	GGAACCCCCA AGCCCGAGGA ATCGGCGTGA CGGTCGCAAA
	CCATCCGGCC

2301	CGGTACAAAT CGGCGCGGCG CTGGGTGATG ACCTGGTGGA
	GAAGTTGAAG

2351	GCCGCGCAGG CCGCCCAGCG GCAACGCATC GAGGCAGAAG
	CACGCCCCGG

2401	TGAATCGTGG CAAGCGGCCG CTGATCGAAT CCGCAAAGAA
	TCCCGGCAAC

2451	CGCCGGCAGC CGGTGCGCCG TCGATTAGGA AGCCGCCCAA
	GGGCGACGAG

2501	CAACCAGATT TTTTCGTTCC GATGCTCTAT GACGTGGGCA
	CCCGCGATAG

2551	TCGCAGCATC ATGGACGTGG CCGTTTTCCG TCTGTCGAAG
	CGTGACCGAC

2601	GAGCTGGCGA GGTGATCCGC TACGAGCTTC CAGACGGGCA
	CGTAGAGGTT

2651	TCCGCAGGGC CGGCCGGCAT GGCCAGTGTG TGGGATTACG
	ACCTGGTACT

2701	GATGGCGGTT TCCCATCTAA CCGAATCCAT GAACCGATAC
	CGGGAAGGGA

2751	AGGGAGACAA GCCCGGCCGC GTGTTCCGTC CACACGTTGC
	GGACGTACTC

2801	AAGTTCTGCC GGCGAGCCGA TGGCGGAAAG CAGAAAGACG
	ACCTGGTAGA

2851	AACCTGCATT CGGTTAAACA CCACGCACGT TGCCATGCAG
	CGTACGAAGA

2901	AGGCCAAGAA CGGCCGCCTG GTGACGGTAT CCGAGGGTGA
	AGCCTTGATT

2951	AGCCGCTACA AGATCGTAAA GAGCGAAACC GGGCGGCCGG
	AGTACATCGA

3001	GATCGAGCTA GCTGATTGGA TGTACCGCGA GATCACAGAA
	GGCAAGAACC

3051	CGGACGTGCT GACGGTTCAC CCCGATTACT TTTTGATCGA
	TCCCGGCATC

3101	GGCCGTTTTC TCTACCGCCT GGCACGCCGC GCCGCAGGCA
	AGGCAGAAGC

3151	CAGATGGTTG TTCAAGACGA TCTACGAACG CAGTGGCAGC
	GCCGGAGAGT

3201	TCAAGAAGTT CTGTTTCACC GTGCGCAAGC TGATCGGGTC
	AAATGACCTG

3251	CCGGAGTACG ATTTGAAGGA GGAGGCGGGG CAGGCTGGCC
	CGATCCTAGT

3301	CATGCGCTAC CGCAACCTGA TCGAGGGCGA AGCATCCGCC
	GGTTCCTAAT

3351	GTACGGAGCA GATGCTAGGG CAAATTGCCC TAGCAGGGGA
	AAAAGGTCGA

3401	AAAGGTCTCT TTCCTGTGGA TAGCACGTAC ATTGGGAACC
	CAAAGCCGTA

3451	CATTGGGAAC CGGAACCCGT ACATTGGGAA CCCAAAGCCG
	TACATTGGGA

3501	ACCGGTCACA CATGTAAGTG ACTGATATAA AAGAGAAAAA
	AGGCGATTTT

3551	TCCGCCTAAA ACTCTTTAAA ACTTATTAAA ACTCTTAAAA
	CCCGCCTGGC

3601	CTGTGCATAA CTGTCTGGCC AGCGCACAGC CGAAGAGCTG
	CAAAAAGCGC

3651	CTACCCTTCG GTCGCTGCGC TCCCTACGCC CCGCCGCTTC
	GCGTCGGCCT

3701	ATCGCGGCCG CTGGCCGCTC AAAAATGGCT GGCCTACGGC
	CAGGCAATCT

3751	ACCAGGGCGC GGACAAGCCG CGCCGTCGCC ACTCGACCGC
	CGGCGCCCAC

3801	ATCAAGGCAC CCTGCCTCGC GCGTTTCGGT GATGACGGTG
	AAAACCTCTG

3851	ACACATGCAG CTCCCGGAGA CGGTCACAGC TTGTCTGTAA
	GCGGATGCCG

3901	GGAGCAGACA AGCCCGTCAG GGCGCGTCAG CGGGTGTTGG
	CGGGTGTCGG

3951	GGCGCAGCCA TGACCCAGTC ACGTAGCGAT AGCGGAGTGT
	ATACTGGCTT

4001	AACTATGCGG CATCAGAGCA GATTGTACTG AGAGTGCACC
	ATATGCGGTG

4051	TGAAATACCG CACAGATGCG TAAGGAGAAA ATACCGCATC
	AGGCGCTCTT

4101	CCGCTTCCTC GCTCACTGAC TCGCTGCGCT CGGTCGTTCG
	GCTGCGGCGA

4151	GCGGTATCAG CTCACTCAAA GGCGGTAATA CGGTTATCCA
	CAGAATCAGG

4201	GGATAACGCA GGAAAGAACA TGTGAGCAAA AGGCCAGCAA
	AAGGCCAGGA

4251	ACCGTAAAAA GGCCGCGTTG CTGGCGTTTT TCCATAGGCT
	CCGCCCCCCT

4301	GACGAGCATC ACAAAAATCG ACGCTCAAGT CAGAGGTGGC
	GAAACCCGAC

4351	AGGACTATAA AGATACCAGG CGTTTCCCCC TGGAAGCTCC
	CTCGTGCGCT

4401	CTCCTGTTCC GACCCTGCCG CTTACCGGAT ACCTGTCCGC
	CTTTCTCCCT

4451	TCGGGAAGCG TGGCGCTTTC TCATAGCTCA CGCTGTAGGT
	ATCTCAGTTC

4501	GGTGTAGGTC GTTCGCTCCA AGCTGGGCTG TGTGCACGAA
	CCCCCCGTTC

4551	AGCCCGACCG CTGCGCCTTA TCCGGTAACT ATCGTCTTGA
	GTCCGCCCTG

4601	GTAAGACACG ACTTATCGCC ACTGGCAGCA GCCACTGGTA
	ACAGGATTAG

4651	CAGAGCGAGG TATGTAGGCG GTGCTACAGA GTTCTTGAAG
	TGGTGGCCTA

4701	ACTACGGCTA CACTAGAAGG ACAGTATTTG GTATCTGCGC
	TCTGCTGAAG

4751	CCAGTTACCT TCGGAAAAAG AGTTGGTAGC TCTTGATCCG
	GCAAACAAAC

4801	CACCGCTGGT AGCGGTGGTT TTTTTGTTTG CAAGCAGCAG
	ATTACGCGCA

4851	GAAAAAAAGG ATCTCAAGAA GATCCTTTGA TCTTTTCTAC
	GGGGTCTGAC

4901	GCTCAGTGGA ACGAAAACTC ACGTTAAGGG ATTTTGGTCA
	TGCATTCTAG

4951	GTACTAAAAC AATTCATCCA GTAAAATATA ATATTTTATT
	TTCTCCCAAT

5001	CAGGCTTGAT CCCCAGTAAG TCAAAAAATA GCTCGACATA
	CTGTTCTTCC

5051	CCGATATCCT CCCTGATCGA CCGGACGCAG AAGGCAATGT
	CATACCACTT

5101	GTCCGCCCTG CCGCTTCTCC CAAGATCAAT AAAGCCACTT
	ACTTTGCCAT

5151	CTTTCACAAA GATGTTGCTG TCTCCCAGGT CGCCGTGGGA
	AAAGACAAGT

5201	TCCTCTTCGG GCTTTTCCGT CTTTAAAAAA TCATACAGCT
	CGCGCGGATC

5251	TTTAAATGGA GTGTCTTCTT CCCAGTTTTC GCAATCCACA
	TCGGCCAGAT

5301	CGTTATTCAG TAAGTAATCC AATTCGGCTA AGCGGCTGTC
	TAAGCTATTC

5351	GTATAGGGAC AATCCGATAT GTCGATGGAG TGAAAGAGCC
	TGATGCACTC

5401	CGCATACAGC TCGATAATCT TTTCAGGGCT TTGTTCATCT
	TCATACTCTT

5451	CCGAGCAAAG GACGCCATCG GCCTCACTCA TGAGCAGATT
	GCTCCAGCCA

5501	TCATGCCGTT CAAAGTGCAG GACCTTTGGA ACAGGCAGCT
	TTCCTTCCAG

5551	CCATAGCATC ATGTCCTTTT CCCGTTCCAC ATCATAGGTG
	GTCCCTTTAT

5601	ACCGGCTGTC CGTCATTTTT AAATATAGGT TTTCATTTTC
	TCCCACCAGC

5651	TTATATACCT TAGCAGGAGA CATTCCTTCC GTATCTTTTA
	CGCAGCGGTA

5701	TTTTTCGATC AGTTTTTTCA ATTCCGGTGA TATTCTCATT
	TTAGCCATTT

5751	ATTATTTCCT TCCTCTTTTC TACAGTATTT AAAGATACCC
	CAAGAAGCTA

5801	ATTATAACAA GACGAACTCC AATTCACTGT TCCTTGCATT
	CTAAAACCTT

5851	AAATACCAGA AAACAGCTTT TTCAAAGTTG TTTTCAAAGT
	TGGCGTATAA

5901	CATAGTATCG ACGGAGCCGA TTTTGAAACC GCGGTGATCA
	CAGGCAGCAA

5951	CGCTCTGTCA TCGTTACAAT CAACATGCTA CCCTCCGCGA
	GATCATCCGT

6001	GTTTCAAACC CGGCAGCTTA GTTGCCGTTC TTCCGAATAG
	CATCGGTAAC

6051	ATGAGCAAAG TCTGCCGCCT TACAACGGCT CTCCCGCTGA
	CGCCGTCCCG

6101	GACTGATGGG CTGCCTGTAT CGAGTGGTGA TTTTGTGCCG
	AGCTGCCGGT

6151	CGGGGAGCTG TTGGCTGGCT GGTGGCAGGA TATATTGTGG
	TGTAAACAAA

6201	TTGACGCTTA GACAACTTAA TAACACATTG CGGACGTTTT
	TAATGTACTG

6251	AATTAACGCC GAATTAATTC GGGGGATCTG GATTTTAGTA
	CTGGATTTTG

6301	GTTTTAGGAA TTAGAAATTT TATTGATAGA AGTATTTTAC
	AAATACAAAT

6351	ACATACTAAG GGTTTCTTAT ATGCTCAACA CATGAGCGAA
	ACCCTATAGG

6401	AACCCTAATT CCCTTATCTG GGAACTACTC ACACATTATT
	ATGGAGAAAC

6451	TCGAGTTAAC CCTGAGACTG TTGGACAGAG CTCATTGGTA
	CCAGGAACAG

6501	GTGGTGGCGG CCCTCGGTGC GCTCGTACTG CTCCACGATG
	GTGTAGTCCT

6551	CGTTGTGGGA GGTGATGTCC AGCTTGGCGT CCACGTAGTA
	GTAGCCGGGC

6601	AGCTGCACGG GCTTCTTGGC CATGTAGATG GACTTGAACT
	CCACCAGGTA

6651	GTGGCCGCCG TCCTTCAGCT TCAGGGCCTT GTGGGTCTCG
	CCCTTCAGCA

6701	CGCCGTCGCG GGGGTAGAGG CGCTCGGTGG AGGCCTCCCA
	GCCCATGGTC

6751	TTCTTCTGCA TCACGGGGCC GTCGGAGGGG AAGTTCACGC
	CGATGAACTT

6801	CACCTTGTAG ATGAAGCAGC CGTCCTGCAG GGAGGAGTCC
	TGGGTCACGG

6851	TCGCCACGCC GCCGTCCTCG AAGTTCATCA CGCGCTCCCA
	CTTGAAGCCC

6901	TCGGGGAAGG ACAGCTTCTT GTAGTCGGGG ATGTCGGCGG
	GGTGCTTCAC

6951	GTACACCTTG GAGCCGTACT GGAACTGGGG GGACAGGATG
	TCCCAGGCGA

7001	AGGGCAGGGG GCCGCCCTTG GTCACCTTCA GCTTCACGGT
	GTTGTGGCCC

7051	TCGTAGGGGC GGCCCTCGCC CTCGCCCTCG ATCTCGAACT
	CGTGGCCGTT

7101	CACGGTGCCC TCCATGCGCA CCTTGAAGCG CATGAACTCG
	GTGATGACGT

7151	TCTCGGAGGA GGCCATTTTG GTAGACTCGA GAGAGATAGA
	TTTGTAGAGA

7201	GAGACTGGTG ATTTCAGCGT GTCCTCTCCA AATGAAATGA
	ACTTCCTTAT

7251	ATAGAGGAAG GTCTTGCGAA GGATAGTGGG ATTGTGCGTC
	ATCCCTTACG

7301	TCAGTGGAGA TATCACATCA ATCCACTTGC TTTGAAGACG
	TGGTTGGAAC

7351	GTCTTCTTTT TCCACGATGC TCCTCGTGGG TGGGGGTCCA
	TCTTTGGGAC

7401	CACTGTCGGC AGAGGCATCT TGAACGATAG CCTTTCCTTT
	ATCGCAATGA

7451	TGGCATTTGT AGGTGCCACC TTCCTTTTCT ACTGTCCTTT
	TGATGAAGTG

7501	ACAGATAGCT GGGCAATGGA ATCCGAGGAG GTTTCCCGAT
	ATTACCCTTT

7551	GTTGAAAAGT CTCAATAGCC CTTTGGTCTT CTGAGACTGT
	ATCTTTGATA

7601	TTCTTGGAGT AGACGAGAGT GTCGTGCTCC ACCATGTTAT
	CACATCAATC

7651	CACTTGCTTT GAAGACGTGG TTGGAACGTC TTCTTTTTCC
	ACGATGCTCC

7701	TCGTGGGTGG GGGTCCATCT TTGGGACCAC TGTCGGCAGA
	GGCATCTTGA

7751	ACGATAGCCT TTCCTTTATC GCAATGATGG CATTTGTAGG
	TGCCACCTTC

7801	CTTTTCTACT GTCCTTTTGA TGAAGTGACA GATAGCTGGG
	CAATGGAATC

7851	CGAGGAGGTT TCCCGATATT ACCCTTTGTT GAAAAGTCTC
	AATAGCCCTT

7901	TGGTCTTCTG AGACTGTATC TTTGATATTC TTGGAGTAGA
	CGAGAGTGTC

7951	GTGCTCCACC ATGTTGGCAA GCTGCTCTAG CCAATACGCA
	AACCGCCTCT

8001	CCCCGCGCGT TGGCCGATTC ATTAATGCAG CTGGCACGAC
	AGGTTTCCCG

8051	ACTGGAAAGC GGGCAGTGAG CGCAACGCAA TTAATGTGAG
	TTAGCTCACT

8101	CATTAGGCAC CCCAGGCTTT ACACTTTATG CTTCCGGCTC
	GTATGTTGTG

8151	TGGAATTGTG AGCGGATAAC AATTTCACAC AGGAAACAGC
	TATGACCATG

8201	ATTACGAATT CAGGTACCAT TTAAATCCTG CAGGGTTTAA
	ACAGTGTTTT

8251	ACTCCTCATA TTAACTTCGG TCATTAGAGG CCACGATTTG
	ACACATTTTT

8301	ACTCAAAACA AAATGTTTGC ATATCTCTTA TAATTTCAAA
	TTCAACACAC

8351	AACAAATAAG AGAAAAAACA AATAATATTA ATTTGAGAAT
	GAACAAAAGG

8401	ACCATATCAT TCATTAACTC TTCTCCATCC ATTTCCATTT
	CACAGTTCGA

8451	TAGCGAAAAC CGAATAAAAA ACACAGTAAA TTACAAGCAC
	AACAAATGGT

8501	ACAAGAAAAA CAGTTTTCCC AATGCCATAA TACTCGAACG
	GCGCGCCTCA

8551	GCCCATATGC AGGCCGCCGT TGAGCGAGAA GTCGGCGCCG
	GTCGAGAAAC

8601	CGGACTCCTC CGACGACAAC CAGGCGCAGA TCGAGGCGAT
	CTCTTCCGGC

8651	AGGCCCAGGC GCTTGACCGG GATCGTCGCG ACGATCTTGT
	CGAGCACGTC

8701	CTGGCGGATC GCCTTGACCA TGTCGGTGGC GATATAGCCC
	GGAGAGACCG

8751	TGTTGACGGT CACGCCCTTG GTCGCCACTT CCTGCGCCAG
	TGCCATGGTG

8801	AAGCCATGCA GGCCGGCCTT GGCGGTGGAG TAGTTGGTCT
	GGCCGAACTG

8851	GCCCTTCTGC CCGTTCACCG ACGAGATGTT GACGATGCGG
	CCCCAGCCAC

8901	GGTCGGCCAT GCCGTCGATC ACCTGCTTGG TGACGTTGAA
	CAGCGAGGTC

8951	AGGTTGGTGT CGATCACCGC ATCCCAGTCG GCGCGGGTCA
	TCTTGCGGAA

9001	CACCACGTCG CGGGTGATAC CGGCGTTGTT GATCAGCACA
	TCAACCTCGC

9051	CGACCTCGGA CTTGACCTTG TCGAATGCGG TCTTGGTCGA
	GTCCCAGTCA

9101	GCCACATTGC CTTCCGAGGC AATGAAATCG AAGCCCAGGG
	CCTTCTGCTG

9151	CTCCAGCCAC TTTTCGCGGC GCGGCGAGTT GGGGCCGCAA
	CCGGCCACCA

9201	CACGAAAGCC ATCCTTGGCC AGCCGCTGGC AAATGGCGGT
	TCCGATACCA

9251	CCCATGCCGC CGGTCACATA CGCAATGCGC TGAGTCACTC
	TAGAATCTCT

9301	CGTCAATGGT GGCAAATAGG AAAGAGTCTC AAACTTCTTC
	TTTCCAATTG

9351	GAGGCCACAC CTGCATGCAC TTTACTCTTC CACCATTGCT
	TGTAATGGAA

9401	GTAATGTCAG TGTTGACCTT CTTCACTGGG AATCCAGTCA
	TGGATTTGAG

9451	GCCGCCGAAT GGAGCCACTG CGGCGGATTG CCCCCTAGAG
	GCACGGCTGA

9501	CTGTTGTCAC AGCGGAAGAG GATATCATAG AAGCCATTTT
	ACTAGTAAGA

9551	AGCTGAAAAT ATCAAAAGAA GGAACAGTCA TTAATCTATT
	GCATGTACTA

9601	GATTTTAGAT ATGAGTGGTC AAAAAAAACT TACGTTAATA
	ACGATGAAGA

9651	AGACAATGAT CCTCAGCACA ATCTCTCTCT CTCTCTCTTG
	GCTTCTCTTC

9701	TGGTGAATAG CACGAGAGAG GGTTTAAATG GAAGGCTCGT
	GGGTCCAAAA

9751	TGGGTGGCGG AGGAAATAGG AGAAGTAGGC AGTGACAAGT
	AATGTAGTAT

9801	TTAGTATTTG ATGAATGACA CATTTTCATT TCAGCATCAT
	CACCAACCAT

9851	CCTTTTGTTC CTTTGCTTCA ACTGTCACTT TCAATTGACA
	AAATTTTTTA

9901	TGTTTTCATG AGAAAACTAA ATTCTTATAA AGATTCATCT
	TCTTGAGTAT

9951	TATACGTGTA GTTTATGAAC AACACGTGTT GTTCCTATAT
	TTTTGTTCTG

10001	TTACCTCTAG AATAAAGTTG TCACCATTTC ATGAGTTCAA
	TTTTTCTTTA

10051	ATAGCCCCAA AAACAAAAGA TGATTCACAA GAAAGATGCG
	AATATTTTGC

10101	TATGAATCTT TTCTTAAGAG AAGCAATTAC ATTTTCACAA
	TAAAATTAGA

10151	TCCACGACTT AACCTAGTTT ATGTTGATTA TTTCTAGTGT
	TAGTATTAAG

10201	CAAAAATAAA ACTTATGAAT ACGAAGGCCT TTAAAGGAAA
	CTAAAGAAAG

10251	GACAAGGTAT AAACGTCCTA GAAAGTTCTA GGGTTTAGGC
	TTAGGGTCTA

10301	AGATATATGC TTTGAGTTTT ATGGCTTAGT AACACATTTT
	TGTAACACTT

10351	CTTTGTAACA TTTCTTGATA TGTTGGAGAA GTAACTCGTC
	TGGACAATAG

10401	TTATTTCCCA TATATAGGAA AAACGGCCTA AACAATAGCC
	GACGGGGACA

10451	AATACATCAT AAACAAAAAA TCCCGGTTAC AAACTTCCTA
	AAAAGCCATT

10501	CGGTCCACTC CGTTAAGCCT GAACTGTGCC TCCGTTATGC
	AAAAACGCCG

10551	TTGACCATCC GTAACCTAGT TGACTGACGG ATTATGGATT
	TAATCCGTTT

10601	TAAGGCCGTT AATAACACCA AAACGACGTC GTTTTGGTGT
	TTTAATTTTT

10651	TTTAACAACA ATTAAACCAA ACGACGTCGT TTTGGTTTAA
	TTAAATTTTT

10701	TTATCAAAAA CCCAAGCCCA AGCCCAAAAC TCTTAACAAA
	AGATAAAGCC

10751	CATCTCTATT TTTTCTAATT AAAACGCACA GCATTATGTT
	TCTTCTCTAA

10801	CGGATATATT TTCAATCTCA TAAATTGGGG ATTAGGGTTC
	TTATTTCCCA

10851	ATTCTCAATC TCTCAAAATT CTCCAAAATT CTCTGAAATT
	GATAATGCCT

10901	TCTTCTTCTT CAAACTCGTT TTTCTCTTTT GACAGTGAGC
	TTGAAGATGA

10951	TAACCATCGT GGTTTTCCTA AGACCTGTCG ATTTGGATGT
	CGTGTTGTGA

11001	TCAGAACCTC AAGAACTCCA AAAAACCTAG GTAGATTATT
	CCATACCTGT

11051	GAGAAAAATT TCAAAAGAGG AGGATTCCAC ACCTGGAAGT
	GGACTGATGT

11101	GTCTTTAGTA GAAGAAGTAG AGGACATAAA GGCTTACATT
	CATAACCGTG

11151	AGAAGTGTCA CGATGAAGAA ATGTTATTAT TGAAGGCTCA
	GATTCGTGGC

11201	TGTGAGAAGA TGATTGAAGG CTTGAAAGGA GAAGCAAAAC
	GTATGAAGCT

11251	AATTGTTGTT GCCGGAATAG TTGTGTTTGG TTGCTTTTTG
	TGTCTCTCTA

11301	AGTGATGTAT GAGATGAATG TTTGTGTATG TGATGTTGTT
	TTGTCTCAAT

11351	AATTAGTCAC TGATGTTGTA TGTAATGTTG TGTTTTGCAT
	CTCTAATTAG

11401	TTAATAATGA ATGTTGTTCT TATGTAATGT TTGATTTAAT
	CAATGGCTTT

11451	TGCAAATAAA TCCATAACAG AACNTATTCA ATATTTTCGA
	AAACATAACA

11501	AAGGTTTCAA AAGAAATTGC ATTAGCATTA GCTGAGTTTT
	CAAACAAAAT

11551	GCATTACATA GACAGACCCT GCTTCATAAT CCCCAAAACA
	CAAAAGAGAA

11601	GCATGCTAAT AACCGCAACT AATATCCAAA GACAGCTTCA
	TAATCCCAAA

11651	ACACAAAAAA AGAAGATTCA TAACCGATCC TTCATGTATT
	TAAAGAAAAT

11701	CAGACAACAA GCAAAGACTT AATCTTCCTG AGTAACTGAT
	GAGCTCAAGT

11751	CGACGTTTAA ACAGTGTTTT ACTCCTCATA TTAACTTCGG
	TCATTAGAGG

11801	CCACGATTTG ACACATTTTT ACTCAAAACA AAATGTTTGC
	ATATCTCTTA

11851	TAATTTCAAA TTCAACACAC AACAAATAAG AGAAAAAACA
	AATAATATTA

11901	ATTTGAGAAT GAACAAAAGG ACCATATCAT TCATTAACTC
	TTCTCCATCC

11951	ATTTCCATTT CACAGTTCGA TAGCGAAAAC CGAATAAAAA
	ACACAGTAAA

12001	TTACAAGCAC AACAAATGGT ACAAGAAAAA CAGTTTTCCC
	AATGCCATAA

12051	TACTCGAACT ACGTATTATT TGCGCTCGAC TGCCAGCGCC
	ACGCCCATGC

12101	CGCCGCCGAT GCACAGCGAG GCCAGGCCCT TCTTCGCGTC
	ACGGCGCTTC

12151	ATCTCGTGCA GCAGCGTCAC CAGGATACGG CAGCCCGACG
	CGCCGATCGG

12201	GTGGCCGATG GCGATGGCGC CGCCGTTCAC ATTGACCTTG
	GAGGTGTCCC

12251	AGCCCATCTG CTGGTGCACC GCCAGCGCCT GCGCGGCAAA
	GGCCTCGTTG

12301	ATCTCCATCA GGTCCAGGTC TTGCGGGGTC CACTCGGCGC
	GCGACAGGGC

12351	GCGCTTGGAG GCCGGCACCG GGCCCATGCC CATCACCTTG
	GGATCGACAC

12401	CGGCGTTGGC ATAGCTCTTG ATCGTGGCCA GCGGGGTCAG
	GCCCAGTTCC

12451	TTGGCCTTGG CCGCCGACAT CACCACCACC GCGGCGGCGC
	CGTCGTTCAG

12501	GCCCGAGGCG TTGGCCGCGG TCACCGTGCC GGCCTTGTCG
	AAGGCGGGCT

12551	TGAGGCCGGA CATGCTGTCC AGCGTGGCGC CCTGGCGCAC
	GAACTCGTCG

12601	GTCTTGAAGG CCACCGGGTC GCCCTTGCGC TGCGGGATCA
	GCACCGGGAC

12651	GATCTCTTCG TCAAACTTGC CGGCCTTCTG CGCGGCTTCG
	GCCTTGTTCT

12701	GCGAGCCGAC GGCGAACTCA TCCTGCGCCT CGCGTGTGAT
	GCCGTATTCC

12751	TTGGCCACGT TCTCGGCGGT GATGCCCATG TGGTACTGGT
	TGTACACGTC

12801	CCACAGGCCG TCGACGATCA TGGTGTCGAC CAGCTTGGCA
	TCGCCCATGC

12851	GGAAACCATC GCGCGAGCCC GGCAGCACGT GCGGGGCGGC
	GCTCATGTTT

12901	TCCTGGCCGC CGGCCACCAC GATCTCGGCG TCGCCCGCCA
	TGATCGCGTT

12951	GGCGGCCAGC ATCACGGCCT TCAGGCCCGA GCCGCACACC
	TTGTTGATGG

13001	TCATGGCCGG CACCATCGCC GGCAGGCCGG CCTTGATCGC
	GGCCTGGCGT

13051	GCGGGGTTCT GGCCCGAACC GGCGGTCAGC ACCTGGCCCA
	TGATGACTTC

13101	GCTCACCTGC TCCGGCTTGA CGCCGGCGCG CTCCAGCGCG
	GCCTTGATGA

13151	CCACGGCACC CAGTTCCGGT GCCGGGATCT TGGCCAGCGA
	GCCGCCAAAC

13201	TTGCCGACCG CGGTGCGGGC GGCGGATACG ATGACAACGT
	CAGTCACTCT

13251	AGAATCTCTC GTCAATGGTG GCAAATAGGA AAGAGTCTCA
	AACTTCTTCT

13301	TTCCAATTGG AGGCCACACC TGCATGCACT TTACTCTTCC
	ACCATTGCTT

13351	GTAATGGAAG TAATGTCAGT GTTGACCTTC TTCACTGGGA
	ATCCAGTCAT

13401	GGATTTGAGG CCGCCGAATG GAGCCACTGC GGCGGATTGC
	CCCCTAGAGG

13451	CACGGCTGAC TGTTGTCACA GCGGAAGAGG ATATCATAGA
	AGCCATTTTG

13501	GATCCAAGAA GCTGAAAATA TCAAAAGAAG GAACAGTCAT
	TAATCTATTG

13551	CATGTACTAG ATTTTAGATA TGAGTGGTCA AAAAAAACTT
	ACGTTAATAA

13601	CGATGAAGAA GACAATGATC CTCAGCACAA TCTCTCTCTC
	TCTCTCTTGG

13651	CTTCTCTTCT GGTGAATAGC ACGAGAGAGG GTTTAAATGG
	AAGGCTCGTG

13701	GGTCCAAAAT GGGTGGCGGA GGAAATAGGA GAAGTAGGCA
	GTGACAAGTA

13751	ATGTAGTATT TAGTATTTGA TGAATGACAC ATTTTCATTT
	CAGCATCATC

13801	ACCAACCATC CTTTTGTTCC TTTGCTTCAA CTGTCACTTT
	CAATTGACAA

13851	AATTTTTTAT GTTTTCATGA GAAAACTAAA TTCTTATAAA
	GATTCATCTT

13901	CTTGAGTATT ATACGTGTAG TTTATGAACA ACACGTGTTG
	TTCCTATATT

13951	TTTGTTCTGT TACCTCTAGA ATAAAGTTGT CACCATTTCA
	TGAGTTCAAT

14001	TTTTCTTTAA TAGCCCCAAA AACAAAAGAT GATTCACAAG
	AAAGATGCGA

14051	ATATTTTGCT ATGAATCTTT TCTTAAGAGA AGCAATTACA
	TTTTCACAAT

14101	AAAATTAGAT CCACGACTTA ACCTAGTTTA TGTTGATTAT
	TTCTAGTGTT

14151	AGTATTAAGC AAAAATAAAA CTTATGAATA CGAAGGCCTT
	TAAAGGAAAC

14201	TAAAGAAAGG ACAAGGTATA AACGTCCTAG AAAGTTCTAG
	GGTTTAGGCT

14251	TAGGGTCTAA GATATATGCT TTGAGTTTTA TGGCTTAGTA
	ACACATTTTT

14301	GTAACACTTC TTTGTAACAT TTCTTGATAT GTTGGAGAAG
	TAACTCGTCT

14351	GGACAATAGT TATTTCCAAT ATATAGGAAA AACGGCCTAA
	ACAATAGCCG

14401	ACGGGGACAA ATACATCATA AACAAAAAAT CCCGGTTACA
	AACGGCCTAA

14451	AAAGCCATTC GGTCCACTCC GTTAAGCCTG AACTGTGCCT
	CCGTTATGCA

14501	AAAACGCCGT TGACCATCCG TAACCTAGTT GACTGACGGA
	TTATGGATTT

14551	AATCCGTTTT AAGGCCGTTA ATAACACCAA AACGACGTCG
	TTTTGGTGTT

14601	TTAATTTTTT TTAACAACAA TTAAACCAAA CGACGTCGTT
	TTGGTTTAAT

14651	TAAATTTTTT TATCAAAAAC CCAAGCCCAA GCCCAAAACT
	CTTAACAAAA

14701	GATAAAGCCC ATCTCTATTT TTTCTAATTA AAACGCACAG
	CATTATGTTT

14751	CTTCTCTAAC GGATATATTT TCAATCTCAT AAATTGGGGA
	TTAGGGTTCT

14801	TATTTCCCAA TTCTCAATCT CTCAAAATTC TCCAAAATTC
	TCTGAAATTG

14851	ATAATGCCTT CTTCTTCTTC AAACTCGTTT TTCTCTTTTG
	ACAGTGAGCT

14901	TGAAGATGAT AACCATCGTG GTTTTCCTAA GACCTGTCGA
	TTTGGATGTC

14951	GTGTTGTGAT CAGAACCTCA AGAACTCCAA AAAACCTAGG
	TAGATTATTC

15001	CATACCTGTG AGAAAAATTT CAAAAGAGGA GGATTCCACA
	CCTGGAAGTG

15051	GACTGATGTG TCTTTAGTAG AAGAAGTAGA GGACATAAAG
	GCTTACATTC

15101	ATAACCGTGA GAAGTGTCAC GATGAAGAAA TGTTATTATT
	GAAGGCTCAG

15151	ATTCGTGGCT GTGAGAAGAT GATTGAAGGC TTGAAAGGAG
	AAGCAAAACG

15201	TATGAAGCTA ATTGTTGTTG CCGGAATAGT TGTGTTTGGT
	TGCTTTTTGT

15251	GTCTCTCTAA GTGATGTATG AGATGAATGT TTGTGTATGT
	GATGTTGTTT

15301	TGTCTCAATA ATTAGTCACT GATGTTGTAT GTAATGTTGT
	GTTTTGCATC

15351	TCTAATTAGT TAATAATGAA TGTTGTTCTT ATGTAATGTT
	TGATTTAATC

15401	AATGGCTTTT GCAAATAAAT CCATAACAGA ACNTATTCAA
	TATTTTCGAA

15451	AACATAACAA AGGTTTCAAA AGAAATTGCA TTAGCATTAG
	CTGAGTTTTC

15501	AAACAAAATG CATTACATAG ACAGACCCTG CTTCATAATC
	CCCAAAACAC

15551	AAAAGAGAAG CATGCTAATA ACCGCAACTA ATATCCAAAG
	ACAGCTTCAT

15601	AATCCCAAAA CACAAAAAAA GAAGATTCAT AACCGATCCT
	TCATGTATTT

15651	AAAGAAAATC AGACAACAAG CAAAGACTTA ATCTTCCTGA
	GTAACTGATG

15701	AGCTCAACTG CAGGTTTAAA CAGTGTTTTA CTCCTCATAT
	TAACTTCGGT

15751	CATTAGAGGC CACGATTTGA CACATTTTTA CTCAAAACAA
	AATGTTTGCA

15801	TATCTCTTAT AATTTCAAAT TCAACACACA ACAAATAAGA
	GAAAAAACAA

15851	ATAATATTAA TTTGAGAATG AACAAAAGGA CCATATCATT
	CATTAACTCT

15901	TCTCCATCCA TTTCCATTTC ACAGTTCGAT AGCGAAAACC
	GAATAAAAAA

15951	CACAGTAAAT TACAAGCACA ACAAATGGTA CAAGAAAAAC
	AGTTTTCCCA

16001	ATGCCATAAT ACTCGAACGC GATCGCTCAG CCCTTGGCTT
	TGACGTAACG

16051	GCCGGGCGCC GCCTCGATCG CGGTGTAGCG GGCGTTGCCG
	GGCTTGGCCT

16101	TGGGCTTGAC CTTCTTGCCG CCATGCTGGG TCAGGAACCC
	GGCCCATTGC

16151	GGCCACCAGC TGCCCGGCAC TTCCTGCGCG CCATCGAACC
	AGGCCTGGGC

16201	ATCGGCGGCG CCACCGTCGT TGATCCAGTA GCTGCGCTTG
	TTCTTGGCCA

16251	CCGAGTTGAT CACGCCGGCG ATATGGCCGG ACGCGCCCAG
	CACGAAGCGG

16301	TTGGCGCCCG GCTTGCCCTG GTTGAGGATG TCGAGCGAAC
	CGTACGCCGA

16351	CATCCACGGC ACGATGTGGT CTTCGCGCGA ACCGTAGATG
	AAGGCCGGGG

16401	CGTCGATCAG GCCGAGGTCG ATCTTTTCGC CGGCCACCGT
	CAGCTTGCCC

16451	GGCACTTTCA GGCTGTTTTC CAGGTAGGTG TTGCGCAGGT
	ACCAGCAGAA

16501	CATCGGGCCC GGCAAATTGG TGCTGTCCGA ATTCCAGAAC
	AGCAGGTCAA

16551	ACGCCGCCGG CTCATTGCCT TTGAGGTAGT TCGACTGCAC
	ATAGTTCCAT

16601	ACCAGGTCGT TCGGACGCAG GCTCGAGAAG GTCGAGGCCA
	GGTCACGGCC

16651	CGGCATCAGG CCGCCATCGC GCAATTGCTG TTCACGCAGC
	GCGACCTGGG

16701	TTTCATCGAC GAAGACGTCG AGCACGCCGG TGTCGCTGAA
	GTCGAGGAAG

16751	GTGGTCAGCA GGGTCAGGCT GGCCGCCGGG TGCTGGCCAC
	GCGCCGCCAG

16801	TACCGCCAGT GCGGTGGCAA CGATGGTGCC GCCCACGCAG
	AAGCCGAACA

16851	TGTTCAGCTT GTCCTGGCCG CTGACGTCCT GGACGATGCG
	GATCGCTTCG

16901	ATCACGCCCT GCTCCACGTA GTCGTCCCAG GTGGTGCCGG
	CCAGCGACTT

16951	GTCCGGATTG CTCCACGAGA TCAGGAACAC GGTGTTGCCC
	TGCTCCACCG

17001	CGTAGCGCAC CAGCGAATTT TCCGGTTGCA GGTCGAGGAT
	GTAGAACTTG

17051	TTGATGCACG GCGGCACCAT CAACAGCGGG CGCTGGCTGA
	CCGTCGGCGT

17101	GGTCGGCGTG TACTGGATCA GCTGGAACAG CGGATTTTCG
	TAAATCACGG

17151	TGCCCGGGGT AATGGCCAGG TTGCGGCCCA CTTCAAAGGC
	CGATTCGTCC

17201	GACAGCGAGA TATGGCCCTT GTTGATATCG CCCAGCATAT
	TGACCAGGCC

17251	ACGCGTCAGG CTCTCGCCCT TGGTTTCAAT CAGTTTTTGC
	TGCGCTTCCG

17301	GGTTGGTGGC GAGGAAGTTC GCGGGCGACA TGGCATCAAT
	CACCTGCTGC

17351	ACGGCAAAGC GTATTTTCTG CTTTTGCTGG GGTGCGGTGT
	CCACCGCCTC

17401	CACCATGGCA CTGAGGAATT TGGCGTTGAG CAGGTAAGAT
	GCGGCATTGA

17451	AGGCCGACAT CGGATTGCCC TGCCAGGCTG CCGAGCTGAA
	GCGGCGGTCG

17501	CTGACGGCTG GCGCCTTGCC AGCCAAAAAA TCCTGCCACA
	ACGCGGTGAA

17551	GTCACGCAGA TAATCGTTTT TCAGCTGCTC CATCGCTTCC
	GGTTTGAGCG

17601	CAACGCCGAT ATCCTGCAAC ATGGTGGCCA TCGGGTTCGC
	CTCGGTGGTG

17651	GGCGCCTTGC TGAACCAGGA TTGCCACTGC AGCTCATCGT
	TGTTCTTGTT

17701	ACTCACTCTA GAATCTCTCG TCAATGGTGG CAAATAGGAA
	AGAGTCTCAA

17751	ACTTCTTCTT TCCAATTGGA GGCCACACCT GCATGCACTT
	TACTCTTCCA

17801	CCATTGCTTG TAATGGAAGT AATGTCAGTG TTGACCTTCT
	TCACTGGGAA

17851	TCCAGTCATG GATTTGAGGC CGCCGAATGG AGCCACTGCG
	GCGGATTGCC

17901	CCCTAGAGGC ACGGCTGACT GTTGTCACAG CGGAAGAGGA
	TATCATAGAA

17951	GCCATTTTTG TACAAAGAAG CTGAAAATAT CAAAAGAAGG
	AACAGTCATT

18001	AATCTATTGC ATGTACTAGA TTTTAGATAT GAGTGGTCAA
	AAAAAACTTA

18051	CGTTAATAAC GATGAAGAAG ACAATGATCC TCAGCACAAT
	CTCTCTCTCT

18101	CTCTCTTGGC TTCTCTTCTG GTGAATAGCA CGAGAGAGGG
	TTTAAATGGA

18151	AGGCTCGTGG GTCCAAAATG GGTGGCGGAG GAAATAGGAG
	AAGTAGGCAG

18201	TGACAAGTAA TGTAGTATTT AGTATTTGAT GAATGACACA
	TTTTCATTTC

18251	AGCATCATCA CCAACCATCC TTTTGTTCCT TTGCTTCAAC
	TGTCACTTTC

18301	AATTGACAAA ATTTTTTATG TTTTCATGAG AAAACTAAAT
	TCTTATAAAG

18351	ATTCATCTTC TTGAGTATTA TACGTGTAGT TTATGAACAA
	CACGTGTTGT

18401	TCCTATATTT TTGTTCTGTT ACCTCTAGAA TAAAGTTGTC
	ACCATTTCAT

18451	GAGTTCAATT TTTCTTTAAT AGCCCCAAAA ACAAAAGATG
	ATTCACAAGA

18501	AAGATGCGAA TATTTTGCTA TGAATCTTTT CTTAAGAGAA
	GCAATTACAT

18551	TTTCACAATA AAATTAGATC CACGACTTAA CCTAGTTTAT
	GTTGATTATT

18601	TCTAGTGTTA GTATTAAGCA AAAATAAAAC TTATGAATAC
	GAAGGCCTTT

18651	AAAGGAAACT AAAGAAAGGA CAAGGTATAA ACGTCCTAGA
	AAGTTCTAGG

18701	GTTTAGGCTT AGGGTCTAAG ATATATGCTT TGAGTTTTAT
	GGCTTAGTAA

18751	CACATTTTTG TAACACTTCT TTGTAACATT TCTTGATATG
	TTGGAGAAGT

18801	AACTCGTCTG GACAATAGTT ATTTCCAATA TATAGGAAAA
	ACGGCCTAAA

18851	CAATAGCCGA CGGGGACAAA TACATCATAA ACAAAAAATC
	CCGGTTACAA

18901	ACTTCCTAAA AAGCCATTCG GTCCACTCCG TTAAGCCTGA
	ACTGTGCCTC

18951	CGTTATGCAA AAACGCCGTT GACCATCCGT AACCTAGTTG
	ACTGACGGAT

19001	TATGGATTTA ATCCGTTTTA AGGCCGTTAA TAACACCAAA
	ACGACGTCGT

19051	TTTGGTGTTT TAATTTTTTT TAACAACAAT TAAACCAAAC
	GACGTCGTTT

19101	TGGTTTAATT AAATTTTTTT ATCAAAAACC CAAGCCCAAG
	CCCAAAACTC

19151	TTAACAAAAG ATAAAGCCCA TCTCTATTTT TTCTAATTAA
	AACGCACAGC

19201	ATTATGTTTC TTCTCTAACG GATATATTTT CAATCTCATA
	AATTGGGGAT

19251	TAGGGTTCTT ATTTCCCAAT TCTCAATCTC TCAAAATTCT
	CCAAAATTCT

19301	CTGAAATTGA TAATGCCTTC TTCTTCTTCA AACTCGTTTT
	TCTCTTTTGA

19351	CAGTGAGCTT GAAGATGATA ACCATCGTGG TTTTCCTAAG
	ACCTGTCGAT

19401	TTGGATGTCG TGTTGTGATC AGAACCTCAA GAACTCCAAA
	AAACCTAGGT

19451	AGATTATTCC ATACCTGTGA GAAAAATTTC AGAAGTAGAG
	GATTCCACAC

19501	CTGGAAGTGG ACTGATGTGT CTTTAGTAGA AGAAGTAGAG
	GACATAAAGG

19551	CTTACATTCA TAACCGTGAG AAGTGTCACG ATGAAGAAAT
	GTTATTATTG

19601	AAGGCTCAGA TTCGTGGCTG TGAGAAGATG ATTGAAGGCT
	TGAAAGGAGA

19651	AGCAAAACGT ATGAAGCTAA TTGTTGTTGC CGGAATAGTT
	GTGTTTGGTT

19701	GCTTTTTGTG TCTCTCTAAG TGATGTATGA GATGAATGTT
	TGTGTATGTG

19751	ATGTTGTTTT GTCTCAATAA TTAGTCACTG ATGTTGTATG
	TAATGTTGTG

19801	TTTTGCATCT CTAATTAGTT AATAATGAAT GTTGTTCTTA
	TGTAATGTTT

19851	GATTTAATCA ATGGCTTTTG CAAATAAATC CATAACAGAA
	CNTATTCAAT

19901	ATTTTCGAAA ACATAACAAA GGTTTCAAAA GAAATTGCAT
	TAGCATTAGC

19951	TGAGTTTTCA AACAAAATGC ATTACATAGA CAGACCCTGC
	TTCATAATCC

20001	CCAAAACACA AAAGAGAAGC ATGCTAATAA CCGCAACTAA
	TATCCAAAGA

20051	CAGCTTCATA ATCCCAAAAC ACAAAAAAAG AAGATTCATA
	ACCGATCCTT

20101	CATGTATTTA AAGAAAATCA GACAACAAGC AAAGACTTAA
	TCTTCCTGAG

20151	TAACTGATGA GCTCAAAAGC TTGGCACTGG CCGTCGTTTT
	ACGACGTCGT

20201	GACTGGGAAA ACCCTGGCGT TACCCAACTT AATCGCCTTG
	CAGCACATCC

20251	CCCTTTCGCC AGCTGGCGTA ATAGCGAAGA GGCCCGCACC
	GATCGCCCTT

20301	CCCAACAGTT GCGCAGCCTG AATGGCGAAT GCTAGAGCAG
	CTTGAGCTTG

20351	GATCAGATTG TCGTTTCCCG CCTTCAGTTT AAACTATCAG
	TGTTTGACAG

20401	GATATATTGG CGGGTAAACC TAAGAGAAAA GAGCGTTTAT
	TAGAATAACG

20451	GATATTTAAA AGGGCGTGAA AAGGTTTATC CGTTCGTCCA
	TTTGTATGTG

Vector: pPhaA-RNAi/35S

(SEQ ID NO: 3)

1	GTCCGTGACC ATGATTACGC CAAGCTTCGA CTGTACAGGA
	TGTTCTAGCT

51	ACTCGAGTAG CTAGAACATC CTGTACAGTC GAGTAGCTAG
	AACATCCTGT

101	ACAGTCGACT AGCTAGAACA TCCTGTACAG TCGAGTAGCT
	AGAACATCCT

151	GTACAGTCGA GTAGCTAGAC ATCCTGTACA GGATCCCTAT
	ATAAGGAAGT

201	TCATTTCATT TGGAGAGAAC ACGGGGGATC GGGTATCGTT
	AATTAAGTTT

251	ATCAACAAGT TTGTACAAAA AAGCAGGCTC CGCGGCCGCC
	CCCTTCACCA

301	TGATCGTCGA CGGCCTGTGG GACGTGTACA ACCAGTACCA
	CATGGGCATC

351	ACCGCCGAGA ACGTGGCCAA GGAATACGGC ATCACACGCG
	AGGCGCAGGA

401	TGAGTTCGCC GTCGGCTCGC AGAACAAGGC CGAAGCCGCG
	CAGAAGGCCG

451	GCAAGTTTGA CGAAGAGATC GTCCCGGTGC TGATCCCGCA
	GCGCAAGGGC

501	GACCCGGTGG CCTTCAAGAC CGACGAGTTC GTGCGCCAGG
	GCGCCACGCT

551	GGACAGCATG TCCGGCCTCA AGCCCGCCTT CGACAAGGCC
	GGCACGGTGA

601	CCGCGGCCAA CGCCTCGGGC CTGAACGACG GCGCCGCCGC
	GGTGGTGGTG

651	ATGTCGGCGG CCAAGGCCAA GGAACTGGGC CTGACCCCGC
	TGGCCACGAT

701	CAAGAGCTAT GCCAACGCCG GTGTCGATCC CAAGGTGATG
	GGCATGGGCC

751	CGGTGCCGGC CTCCAAGCGC GCCCTGTCGC GCGCCGAGTG
	GACCCCGCAA

801	GACCTGGACC TGATGGAGAT CAACGAGGCC TTTGCCGCGC
	AGGCGCTGGC

851	GGTGCACCAG CAGATGGGCT GGGACACCTC CAAGGTCAAT
	GTGAAAGGGT

901	GGGCGCGCCG ACCCAGCTTT CTTGTACAAA GTGGTTGATC
	CTGCAGGGTC

951	CGTCGCTTCT CTTCCATTTC TTCTCATTTT CGATTTTGAT
	TCTTATTTCT

1001	TTCCAGTAGC TCCTGCTCTG TGAATTTCTC CGCTCACGAT
	AGATCTGCTT

1051	ATACTCCTTA CATTCAACCT TAGATCTGGT CTCGATTCTC
	TGTTTCTCTG

1101	TTTTTTTCTT TTGGTCGAGA ATCTGATGTT TGTTTATGTT
	CTGTCACCAT

1151	TAATAATAAT GAACTCTCTC ATTCATACAA TGATTAGTTT
	CTCTCGTCTA

1201	CAAAACGATA TGTTGCATTT TCACTTTTCT TCTTTTTTTC
	TAAGATGATT

1251	TGCTTTGACC AATTTGTTTA GATCTTTATT CTATTTTATT
	TTCTGGTGGG

1301	TTGGTGGAAA TTGAAAAAAA AAAAACAGCA TAAATTGTTA
	TTTGTTAATG

1351	TATTCATTTT TTGGCTATTT GTTCTGGGTA AAAATCTGCT
	TCTACTATTG

1401	AATCTTTCCT GGATTTTTTA CTCCTATTGG GTTTTTATAG
	TAAAAATACA

1451	TAATAAAAGG AAAACAAAAG TTTTATAGAT TCTCTTAAAC
	CCCTTACGAT

1501	AAAAGTTGGA ATCAAAATAA TTCAGGATCA GATGCTCTTT
	GATTGATTCA

1551	GATGCGATTA CAGTTGCATG GCAAATTTTC TAGATCCGTC
	GTCACATTTT

1601	ATTTTCTGTT TAAATATCTA AATCTGATAT ATGATGTCGA
	CAAATTCTGG

1651	TGGCTTATAC ATCACTTCAA CTGTTTTCTT TTGGCTTTGT
	TTGTCAACTT

1701	GGTTTTCAAT ACGATTTGTG ATTTCGATCG CTGAATTTTT
	AATACAAGCA

1751	AACTGATGTT AACCACAAGC AAGAGATGTG ACCTGCCTTA
	TTAACATCGT

1801	ATTACTTACT ACTAGTCGTA TTCTCAACGC AATCGTTTTT
	GTATTTCTCA

1851	CATTATGCCG CTTCTCTACT CTTTATTCCT TTTGGTCCAC
	GCATTTTCTA

1901	TTTGTGGCAA TCCCTTTCAC AACCTGATTT CCCACTTTGG
	ATCATTTGTC

1951	TGAAGACTCT CTTGAATCGT TACCACTTGT TTCTTGTGCA
	TGCTCTGTTT

2001	TTTAGAATTA ATGATAAAAC TATTCCATAG TCTTGAGTTT
	TCAGCTTGTT

2051	GATTCTTTTG CTTTTGGTTT TCTGCAGGTT TAAACATCAA
	CCACTTTGTA

2101	CAAGAAAGCT GGGTCGGCGC GCCCACCCTT TCACATTGAC
	CTTGGAGGTG

2151	TCCCAGCCCA TCTGCTGGTG CACCGCCAGC GCCTGCGCGG
	CAAAGGCCTC

2201	GTTGATCTCC ATCAGGTCCA GGTCTTGCGG GGTCCACTCG
	GCGCGCGACA

2251	GGGCGCGCTT GGAGGCCGGC ACCGGGCCCA TGCCCATCAC
	CTTGGGATCG

2301	ACACCGGCGT TGGCATAGCT CTTGATCGTG GCCAGCGGGG
	TCAGGCCCAG

2351	TTCCTTGGCC TTGGCCGCCG ACATCACCAC CACCGCGGCG
	GCGCCGTCGT

2401	TCAGGCCCGA GGCGTTGGCC GCGGTCACCG TGCCGGCCTT
	GTCGAAGGCG

2451	GGCTTGAGGC CGGACATGCT GTCCAGCGTG GCGCCCTGGC
	GCACGAACTC

2501	GTCGGTCTTG AAGGCCACCG GGTCGCCCTT GCGCTGCGGG
	ATCAGCACCG

2551	GGACGATCTC TTCGTCAAAC TTGCCGGCCT TCTGCGCGGC
	TTCGGCCTTG

2601	TTCTGCGAGC CGACGGCGAA CTCATCCTGC GCCTCGCGTG
	TGATGCCGTA

2651	TTCCTTGGCC ACGTTCTCGG CGGTGATGCC CATGTGGTAC
	TGGTTGTACA

2701	CGTCCCACAG GCCGTCGACG ATCATGGTGA AGGGGGCGGC
	CGCGGAGCCT

2751	GCTTTTTTGT ACAAACTTGT TGATCTCGAG CGGCGCGCCG
	TTCGAGTATT

2801	ATGGCATTGG GAAAACTGTT TTTCTTGTAC CATTTGTTGT
	GCTTGTAATT

2851	TACTGTGTTT TTTATTCGGT TTTCGCTATC GAACTGTGAA
	ATGGAAATGG

2901	ATGGAGAAGA GTTAATGAAT GATATGGTCC TTTTGTTCAT
	TCTCAAATTA

2951	ATATTATTTG TTTTTTCTCT TATTTGTTGT GTGTTGAATT
	TGAAATTATA

3001	AGAGATATGC AAACATTTTG TTTTGAGTAA AAATGTGTCA
	AATCGTGGCC

3051	TCTAATGACC GAAGTTAATA TGAGGAGTAA AACACTGTTT
	AAACCCTGCA

3101	GGATTTAAAT AGAAGGTAAT TATCCAAGAT GTAGCATCAA
	GAATCCAATG

3151	TTTACGGGAA AAACTATGGA AGTATTATGT GAGCTCAGCA
	AGAAGCAGAT

3201	CAATATGCGG CACATATGCA ACCTATGTTC AAAAATGAAG
	AATGTACAGA

3251	TACAAGATCC TATACTGCCA GAATACGAAG AAGAATACGT
	AGAAATTGAA

3301	AAAGAAGAAC CAGGCGAAGA AAAGAATCTT GAAGACGTAA
	GCACTGACGA

3351	CAACAATGAA AAGAAGAAGA TAAGGTCGGT GATTGTGAAA
	GAGACATAGA

3401	GGACACATGT AAGGTGGAAA ATGTAAGGGC GGAAAGTAAC
	CTTATCACAA

3451	AGGAATCTTA TCCCCCACTA CTTATCCTTT TATATTTTTC
	CGTGTCATTT

3501	TTGCCCTTGA GTTTTCCTAT ATAAGGAACC AAGTTCGGCA
	TTTGTGAAAA

3551	CAAGAAAAAA TTGGTGTAAG CTATTTTCTT TGAAGTACTG
	AGGATACAAC

3601	TTCAGAGAAA TTTGTAAGAA AGTGGATCGA AACCATGGCC
	TCCTCCGAGA

3651	ACGTCATCAC CGAGTTCATG CGCTTCAAGG TGCGCATGGA
	GGGCACCGTG

3701	AACGGCCACG AGTTCGAGAT CGAGGGCGAG GGCGAGGGCC
	GCCCCTACGA

3751	GGGCCACAAC ACCGTGAAGC TGAAGGTGAC CAAGGGCGGC
	CCCCTGCCCT

3801	TCGCCTGGGA CATCCTGTCC CCCCAGTTCC AGTACGGCTC
	CAAGGTGTAC

3851	GTGAAGCACC CCGCCGACAT CCCCGACTAC AAGAAGCTGT
	CCTTCCCCGA

3901	GGGCTTCAAG TGGGAGCGCG TGATGAACTT CGAGGACGGC
	GGCGTGGCGA

3951	CCGTGACCCA GGACTCCTCC CTGCAGGACG GCTGCTTCAT
	CTACAAGGTG

4001	AAGTTCATCG GCGTGAACTT CCCCTCCGAC GGCCCCGTGA
	TGCAGAAGAA

4051	GACCATGGGC TGGGAGGCCT CCACCGAGCG CCTGTACCCC
	CGCGACGGCG

4101	TGCTGAAGGG CGAGACCCAC AAGGCCCTGA AGCTGAAGGA
	CGGCGGCCAC

4151	TACCTGGTGG AGTTCAAGTC CATCTACATG GCCAAGAAGC
	CCGTGCAGCT

4201	GCCCGGCTAC TACTACGTGG ACGCCAAGCT GGACATCACC
	TCCCACAACG

4251	AGGACTACAC CATCGTGGAG CAGTACGAGC GCACCGAGGG
	CCGCCACCAC

4301	CTGTTCCTGG TACCAATGAG CTCTGTCCAA CAGTCTCAGG
	GTTAATGTCT

4351	ATGTATCTTA AATAATGTTG TCGGCGATCG TTCAAACATT
	TGGCAATAAA

4401	GTTTCTTAAG ATTGAATCCT GTTGCCGGTC TTGCGATGAT
	TATCATATAA

4451	TTTCTGTTGA ATTACGTTAA GCATGTAATA ATTAACATGT
	AATGCATGAC

4501	GTTATTTATG AGATGGGTTT TTATGATTAG AGTCCCGCAA
	TTATACATTT

4551	AATACGCGAT AGAAAACAAA ATATACCGCG CAAACTAGGA
	TAAATTATCG

4601	CGCGCGGTGT CATCTATGTT ACTAGATCGG GAATTAAACT
	ATCAGTGTTT

4651	GACAGGATAT ATTGGCGGGT AAACCTAAGA GAAAAGAGCG
	TTTATTAGAA

4701	TAACGGATAT TTAAAAGGGC GTGAAAAGGT TTATCCGTTC
	GTCCATTTGT

4751	ATGTGCATGC CAACCACAGG GTTCCCCTCG GGATCAAAGT
	ACTTTGATCC

4801	AACCCCTCCG CTGCTATAGT GCAGTCGGCT TCTGACGTTC
	AGTGCAGCCG

4851	TCTTCTGAAA ACGACATGTC GCACAAGTCC TAAGTTACGC
	GACAGGCTGC

4901	CGCCCTGCCC TTTTCCTGGC GTTTTCTTGT CGCGTGTTTT
	AGTCGCATAA

4951	AGTAGAATAC TTGCGACTAG AACCGGAGAC ATTACGCCAT
	GAACAAGAGC

5001	GCCGCCGCTG GCCTGCTGGG CTATGCCCGC GTCAGCACCG
	ACGACCAGGA

5051	CTTGACCAAC CAACGGGCCG AACTGCACGC GGCCGGCTGC
	ACCAAGCTGT

5101	TTTCCGAGAA GATCACCGGC ACCAGGCGCG ACCGCCCGGA
	GCTGGCCAGG

5151	ATGCTTGACC ACCTACGCCC TGGCGACGTT GTGACAGTGA
	CCAGGCTAGA

5201	CCGCCTGGCC CGCAGCACCC GCGACCTACT GGACATTGCC
	GAGCGCATCC

5251	AGGAGGCCGG CGCGGGCCTG CAGAGCCGTG CAGAGCCGTG
	GGCCGACACC

5301	ACCACGCCGG CCGGCCGCAT GGTGTTGACC GTGTTCGCCG
	GCATTGCCGA

5351	GTTCGAGCGT TCCCTAATCA TCGACCGCAC CCGGAGCGGG
	CGCGAGGCCG

5401	CCAAGGCCCG AGGCGTGAAG TTTGGCCCCC GCCCTACCCT
	CACCCCGGCA

5451	CAGATCGCGC ACGCCCGCGA GCTGATCGAC CAGGAAGGCC
	GCACCGTGAA

5501	AGAGGCGGCT GCACTGCTTG GCGTGCATCG CTCGACCCTG
	TACCGCGCAC

5551	TTGAGCGCAG CGAGGAAGTG ACGCCCACCG AGGCCAGGCG
	GCGCGGTGCC

5601	TTCCGTGAGG ACGCATTGAC CGAGGCCGAC GCCCTGGCGG
	CCGCCGAGAA

5651	TGAACGCCAA GAGGAACAAG CATGAAACCG CACCAGGACG
	GCCAGGACGA

5701	ACCGTTTTTC ATTACCGAAG AGATCGAGGC GGAGATGATC
	GCGGCCGGGT

5751	ACGTGTTCGA GCCGCCCGCG CACGTCTCAA CCGTGCGGCT
	GCATGAAATC

5801	CTGGCCGGTT TGTCTGATGC CAAGCTGGCG GCCTGGCCGG
	CCAGCTTGGC

5851	CGCTGAAGAA ACCGAGCGCC GCCGTCTAAA AAGGTGATGT
	GTATTTGAGT

5901	AAAACAGCTT GCGTCATGCG GTCGCTGCGT ATATGATGCG
	ATGAGTAAAT

5951	AAACAAATAC GCAAGGGGAA CGCATGAAGG TTATCGCTGT
	ACTTAACCAG

6001	AAAGGCGGGT CAGGCAAGAC GACCATCGCA ACCCATCTAG
	CCCGCGCCCT

6051	GCAACTCGCC GGGGCCGATG TTCTGTTAGT CGATTCCGAT
	CCCCAGGGCA

6101	GTGCCCGCGA TTGGGCGGCC GTGCGGGAAG ATCAACCGCT
	AACCGTTGTC

6151	GGCATCGACC GCCCGACGAT TGACCGCGAC GTGAAGGCCA
	TCGGCCGGCG

6201	CGACTTCGTA GTGATCGACG GAGCGCCCCA GGCGGCGGAC
	TTGGCTGTGT

6251	CCGCGATCAA GGCAGCCGAC TTCGTGCTGA TTCCGGTGCA
	GCCAAGCCCT

6301	TACGACATAT GGGCCACCGC CGACCTGGTG GAGCTGGTTA
	AGCAGCGCAT

6351	TGAGGTCACG GATGGAAGGC TACAAGCGGC CTTTGTCGTG
	TCGCGGGCGA

6401	TCAAAGGCAC GCGCATCGGC GGTGAGGTTG CCGAGGCGCT
	GGCCGGGTAC

6451	GAGCTGCCCA TTCTTGAGTC CCGTATCACG CAGCGCGTGA
	GCTACCCAGG

6501	CACTGCCGCC GCCGGCACAA CCGTTCTTGA ATCAGAACCC
	GAGGGCGACG

6551	CTGCCCGCGA GGTCCAGGCG CTGGCCGCTG AAATTAAATC
	AAAACTCATT

6601	TGAGTTAATG AGGTAAAGAG AAAATGAGCA AAAGCACAAA
	CACGCTAAGT

6651	GCCGGCCGTC CGAGCGCACG CAGCAGCAAG GCTGCAACGT
	TGGCCAGCCT

6701	GGCAGACACG CCAGCCATGA AGCGGGTCAA CTTTCAGTTG
	CCGGCGGAGG

6751	ATCACACCAA GCTGAAGATG TACGCGGTAC GCCAAGGCAA
	GACCATTACC

6801	GAGCTGCTAT CTGAATACAT CGCGCAGCTA CCAGAGTAAA
	TGAGCAAATG

6851	AATAAATGAG TAGATGAATT TTAGCGGCTA AAGGAGGCGG
	CATGGAAAAT

6901	CAAGAACAAC CAGGCACCGA CGCCGTGGAA TGCCCCATGT
	GTGGAGGAAC

6951	GGGCGGTTGG CCAGGCGTAA GCGGCTGGGT TGTCTGCCGG
	CCCTGCAATG

7001	GCACTGGAAC CCCCAAGCCC GAGGAATCGG CGTGACGGTC
	GCAAACCATC

7051	CGGCCCGGTA CAAATCGGCG CGGCGCTGGG TGATGACCTG
	GTGGAGAAGT

7101	TGAAGGCCGC GCAGGCCGCC CAGCGGCAAC GCATCGAGGC
	AGAAGCACGC

7151	CCCGGTGAAT CGTGGCAAGC GGCCGCTGAT CGAATCCGCA
	AAGAATCCCG

7201	GCAACCGCCG GCAGCCGGTG CGCCGTCGAT TAGGAAGCCG
	CCCAAGGGCG

7251	ACGAGCAACC AGATTTTTTC GTTCCGATGC TCTATGACGT
	GGGCACCCGC

7301	GATAGTCGCA GCATCATGGA CGTGGCCGTT TTCCGTCTGT
	CGAAGCGTGA

7351	CCGACGAGCT GGCGAGGTGA TCCGCTACGA GCTTCCAGAC
	GGGCACGTAG

7401	AGGTTTCCGC AGGGCCGGCC GGCATGGCCA GTGTGTGGGA
	TTACGACCTG

7451	GTACTGATGG CGGTTTCCCA TCTAACCGAA TCCATGAACC
	GATACCGGGA

7501	AGGGAAGGGA GACAAGCCCG GCCGCGTGTT CCGTCCACAC
	GTTGCGGACG

7551	TACTCAAGTT CTGCCGGCGA GCCGATGGCG GAAAGCAGAA
	AGACGACCTG

7601	GTAGAAACCT GCATTCGGTT AAACACCACG CACGTTGCCA
	TGCAGCGTAC

7651	GAAGAAGGCC AAGAACGGCC GCCTGGTGAC GGTATCCGAG
	GGTGAAGCCT

7701	TGATTAGCCG CTACAAGATC GTAAAGAGCG AAACCGGGCG
	GCCGGAGTAC

7751	ATCGAGATCG AGCTAGCTGA TTGGATGTAC CGCGAGATCA
	CAGAAGGCAA

7801	GAACCCGGAC GTGCTGACGG TTCACCCCGA TTACTTTTTG
	ATCGATCCCG

7851	GCATCGGCCG TTTTCTCTAC CGCCTGGCAC GCCGCGCCGC
	AGGCAAGGCA

7901	GAAGCCAGAT GGTTGTTCAA GACGATCTAC GAACGCAGTG
	GCAGCGCCGG

7951	AGAGTTCAAG AAGTTCTGTT TCACCGTGCG CAAGCTGATC
	GGGTCAAATG

8001	ACCTGCCGGA GTACGATTTG AAGGAGGAGG CGGGGCAGGC
	TGGCCCGATC

8051	CTAGTCATGC GCTACCGCAA CCTGATCGAG GGCGAAGCAT
	CCGCCGGTTC

8101	CTAATGTACG GAGCAGATGC TAGGGCAAAT TGCCCTAGCA
	GGGGAAAAAG

8151	GTCGAAAAGG TCTCTTTCCT GTGGATAGCA CGTACATTGG
	GAACCCAAAG

8201	CCGTACATTG GGAACCGGAA CCCGTACATT GGGAACCCAA
	AGCCGTACAT

8251	TGGGAACCGG TCACACATGT AAGTGACTGA TATAAAAGAG
	AAAAAAGGCG

8301	ATTTTTCCGC CTAAAACTCT TTAAAACTTA TTAAAACTCT
	TAAAACCCGC

8351	CTGGCCTGTG CATAACTGTC TGGCCAGCGC ACAGCCGAAG
	AGCTGCAAAA

8401	AGCGCCTACC CTTCGGTCGC TGCGCTCCCT ACGCCCCGCC
	GCTTCGCGTC

8451	GGCCTATCGC GGCCGCTGGC CGCTCAAAAA TGGCTGGCCT
	ACGGCCAGGC

8501	AATCTACCAG GGCGCGGACA AGCCGCGCCG TCGCCACTCG
	ACCGCCGGCG

8551	CCCACATCAA GGCACCCTGC CTCGCGCGTT TCGGTGATGA
	CGGTGAAAAC

8601	CTCTGACACA TGCAGCTCCC GGAGACGGTC ACAGCTTGTC
	TGTAAGCGGA

8651	TGCCGGGAGC AGACAAGCCC GTCAGGGCGC GTTGGCGGGT
	GTTGGCGGGT

8701	GTCGGGGCGC AGCCATGACC CAGTCACGTA GCGATAGCGG
	AGTGTATACT

8751	GGCTTAACTA TGCGGCATCA GAGCAGATTG TACTGAGAGT
	GCACCATATG

8801	CGGTGTGAAA TACCGCACAG ATGCGTAAGG AGAAAATACC
	GCATCAGGCG

8851	CTCTTCCGCT TCCTCGCTCA CTGACTCGCT GCGCTCGGTC
	GTTCGGCTGC

8901	GGCGAGCGGT ATCAGCTCAC TCAAAGGCGG TAATACGGTT
	ATCCACAGAA

8951	TCAGGGGATA ACGCAGGAAA GAACATGTGA GCAAAAGGCC
	AGCAAAAGGC

9001	CAGGAACCGT AAAAAGGCCG CGTTGCTGGC GTTTTTCCAT
	AGGCTCCGCC

9051	CCCCTGACGA GCATCACAAA AATCGACGCT CAAGTCAGAG
	GTGGCGAAAC

9101	CCGACAGGAC TATAAAGATA CCAGGCGTTT CCCCCTGGAA
	GCTCCCTCGT

9151	GCGCTCTCCT GTTCCGACCC TGCCGCTTAC CGGATACCTG
	TCCGCCTTTC

9201	TCCCTTCGGG AAGCGTGGCG CTTTCTCATA GCTCACGCTG
	TAGGTATCTC

9251	AGTTCGGTGT AGGTCGTTCG CTCCAAGCTG GGCTGTGTGC
	ACGAACCCCC

9301	CGTTCAGCCC GACCGCTGCG CCTTATCCGG TAACTATCGT
	CTTGAGTCCA

9351	ACCCGGTAAG ACACGACTTA TCGCCACTGG CAGCAGCCAC
	TGGTAACAGG

9401	ATTAGCAGAG CGAGGTATGT AGGCGGTGCT ACAGAGTTCT
	TGAAGTGGTG

9451	GCCTAACTAC GGCTACACTA GAAGGACAGT ATTTGGTATC
	TGCGCTCTGC

9501	TGAAGCCAGT TACCTTCGGA AAAAGAGTTG GTAGCTCTTG
	ATCCGGCAAA

9551	CAAACCACCG CTGGTAGCGG TGGTTTTTTT GTTTGCAAGC
	AGCAGATTAC

9601	GCGCAGAAAA AAAGGATCTC AAGAAGATCC TTTGATCTTT
	TCTACGGGGT

9651	CTGACGCTCA GTGGAACGAA AACTCACGTT AAGGGATTTT
	GGTCATGCAT

9701	TCTAGGTACT AAAACAATTC ATCCAGTAAA ATATAATATT
	TTATTTTCTC

9751	CCAATCAGGC TTGATCCCCA GTAAGTCAAA AAATAGCTCG
	ACATACTGTT

9801	CTTCCCCGAT ATCCTCCCTG ATCGACCGGA CGCAGAAGGC
	AATGTCATAC

9851	CACTTGTCCG CCCTGCCGCT TCTCCCAAGA TCAATAAAGC
	CACTTACTTT

9901	GCCATCTTTC ACAAAGATGT TGCTGTCTCC CAGGTCGCCG
	TGGGAAAAGA

9951	CAAGTTCCTC TTCGGGCTTT TCCGTCTTTA AAAAATCATA
	CAGCTCGCGC

10001	GGATCTTTAA ATGGAGTGTC TTCTTCCCAG TTTTCGCAAT
	CCACATCGGC

10051	CAGATCGTTA TTCAGTAAGT AATCCAATTC GGCTAAGCGG
	CTGTCTAAGC

10101	TATTCGTATA GGGACAATCC GATATGTCGA TGGAGTGAAA
	GAGCCTGATG

10151	CACTCCGCAT ACAGCTCGAT AATCTTTTCA GGGCTTTGTT
	CATCTTCATA

10201	CTCTTCCGAG CAAAGGACGC CATCGGCCTC ACTCATGAGC
	AGATTGCTCC

10251	AGCCATCATG CCGTTCAAAG TGCAGGACCT TTGGAACAGG
	CAGCTTTCCT

10301	TCCAGCCATA GCATCATGTC CTTTTCCCGT TCCACATCAT
	AGGTGGTCCC

10351	TTTATACCGG CTGTCCGTCA TTTTTAAATA TAGGTTTTCA
	TTTTCTCCCA

10401	CCAGCTTATA TACCTTAGCA GGAGACATTC CTTCCGTATC
	TTTTACGCAG

10451	CGGTATTTTT CGATCAGTTT TTTCAATTCC GGTGATATTC
	TCATTTTAGC

10501	CATTTATTAT TTCCTTCCTC TTTTCTACAG TATTTAAAGA
	TACCCCAAGA

10551	AGCTAATTAT AACAAGACGA ACTCCAATTC ACTGTTCCTT
	GCATTCTAAA

10601	ACCTTAAATA CCAGAAAACA GCTTTTTCAA AGTTGTTTTC
	AAAGTTGGCG

10651	TATAACATAG TATCGACGGA GCCGATTTTG AAACCGCGGT
	GATCACAGGC

10701	AGCAACGCTC TGTCATCGTT ACAATCAACA TGCTACCCTC
	CGCGAGATCA

10751	TCCGTGTTTC AAACCCGGCA GCTTAGTTGC CGTTCTTCCG
	AATAGCATCG

10801	GTAACATGAG CAAAGTCTGC CGCCTTACAA CGGCTCTCCC
	GCTGACGCCG

10851	TCCCGGACTG ATGGGCTGCC TGTATCGAGT GGTGATTTTG
	TGCCGAGCTG

10901	CCGGTCGGGG AGCTGTTGGC TGGCTGGTGG CAGGATATAT
	TGTGGTGTAA

10951	ACAAATTGAC GCTTAGACAA CTTAATAACA CATTGCGGAC
	GTTTTTAATG

11001	TACTGAATTA ACGCCGAATT AATTCCTAGG CCACCATGTT
	GGGCCCGGGG

11051	CGCGCCGTAC GTAGTGTTTA TCTTTGTTGC TTTTCTGAAC
	AATTTATTTA

11101	CTATGTAAAT ATATTATCAA TGTTTAATCT ATTTTAATTT
	GCACATGAAT

11151	TTTCATTTTA TTTTTACTTT ACAAAACAAA TAAATATATA
	TGCAAAAAAA

11201	TTTACAAACG ATGCACGGGT TACAAACTAA TTTCATTAAA
	TGCTAATGCA

11251	GATTTTGTGA AGTAAAACTC CAATTATGAT GAAAAATACC
	ACCAACACCA

11301	CCTGCGAAAC TGTATCCCAA CTGTCCTTAA TAAAAATGTT
	AAAAAGTATA

11351	TTATTCTCAT TTGTCTGTCA TAATTTATGT ACCCCACTTT
	AATTTTTCTG

11401	ATGTACTAAA CCGAGGGCAA ACTGAAACCT GTTCCTCATG
	CAAAGCCCCT

11451	ACTCACCATG TATCATGTAC GTGTCATCAC CCAACAACTC
	CACTTTTGCT

11501	ATATAACAAC ACCCCCGTCA CACTCTCCCT CTCTAACACA
	CACCCCACTA

11551	ACAATTCCTT CACTTGCAGC ACTGTTGCAT CATCATCTTC
	ATTGCAAAAC

11601	CCTAAACTTC ACCTTCAACC GCGGCCGCAT GGCTTCTATG
	ATATCCTCTT

11651	CCGCTGTGAC AACAGTCAGC CGTGCCTCTA GGGGGCAATC
	CGCCGCAGTG

11701	GCTCCATTCG GCGGCCTCAA ATCCATGACT GGATTCCCAG
	TGAAGAAGGT

11751	CAACACTGAC ATTACTTCCA TTACAAGCAA TGGTGGAAGA
	GTAAAGTGCA

11801	TGCAGGTGTG GCCTCCAATT GGAAAGAAGA AGTTTGAGAC
	TCTTTCCTAT

11851	TTGCCACCAT TGACGAGAGA TTCTAGAGTG AGTAACAAGA
	ACAACGATGA

11901	GCTGCAGTGG CAATCCTGGT TCAGCAAGGC GCCCACCACC
	GAGGCGAACC

11951	CGATGGCCAC CATGTTGCAG GATATCGGCG TTGCGCTCAA
	ACCGGAAGCG

12001	ATGGAGCAGC TGAAAAACGA TTATCTGCGT GACTTCACCG
	CGTTGTGGCA

12051	GGATTTTTTG GCTGGCAAGG CGCCAGCCGT CAGCGACCGC
	CGCTTCAGCT

12101	CGGCAGCCTG GCAGGGCAAT CCGATGTCGG CCTTCAATGC
	CGCATCTTAC

12151	CTGCTCAACG CCAAATTCCT CAGTGCCATG GTGGAGGCGG
	TGGACACCGC

12201	ACCCCAGCAA AAGCAGAAAA TACGCTTTGC CGTGCAGCAG
	GTGATTGATG

12251	CCATGTCGCC CGCGAACTTC CTCGCCACCA ACCCGGAAGC
	GCAGCAAAAA

12301	CTGATTGAAA CCAAGGGCGA GAGCCTGACG CGTGGCCTGG
	TCAATATGCT

12351	GGGCGATATC AACAAGGGCC ATATCTCGCT GTCGGACGAA
	TCGGCCTTTG

12401	AAGTGGGCCG CAACCTGGCC ATTACCCCGG GCACCGTGAT
	TTACGAAAAT

12451	CCGCTGTTCC AGCTGATCCA GTACACGCCG ACCACGCCGA
	CGGTCAGCCA

12501	GCGCCCGCTG TTGATGGTGC CGCCGTGCAT CAACAAGTTC
	TACATCCTCG

12551	ACCTGCAACC GGAAAATTCG CTGGTGCGCT ACGCGGTGGA
	GCAGGGCAAC

12601	ACCGTGTTCC TGATCTCGTG GAGCAATCCG GACAAGTCGC
	TGGCCGGCAC

12651	CACCTGGGAC GACTACGTGG AGCAGGGCGT GATCGAAGCG
	ATCCGCATCG

12701	TCCAGGACGT CAGCGGCCAG GACAAGCTGA ACATGTTCGG
	CTTCTGCGTG

12751	GGCGGCACCA TCGTTGCCAC CGCACTGGCG GTACTGGCGG
	CGCGTGGCCA

12801	GCACCCGGCG GCCAGCCTGA CCCTGCTGAC CACCTTCCTC
	GACTTCAGCG

12851	ACACCGGCGT GCTCGACGTC TTCGTCGATG AAACCCAGGT
	CGCGCTGCGT

12901	GAACAGCAAT TGCGCGATGG CGGCCTGATG CCGGGCCGTG
	ACCTGGCCTC

12951	GACCTTCTCG AGCCTGCGTC CGAACGACCT GGTATGGAAC
	TATGTGCAGT

13001	CGAACTACCT CAAAGGCAAT GAGCCGGCGG CGTTTGACCT
	GCTGTTCTGG

13051	AATTCGGACA GCACCAATTT GCCGGGCCCG ATGTTCTGCT
	GGTACCTGCG

13101	CAACACCTAC CTGGAAAACA GCCTGAAAGT GCCGGGCAAG
	CTGACGGTGG

13151	CCGGCGAAAA GATCGACCTC GGCCTGATCG ACGCCCCGGC
	CTTCATCTAC

13201	GGTTCGCGCG AAGACCACAT CGTGCCGTGG ATGTCGGCGT
	ACGGTTCGCT

13251	CGACATCCTC AACCAGGGCA AGCCGGGCGC CAACCGCTTC
	GTGCTGGGCG

13301	CGTCCGGCCA TATCGCCGGC GTGATCAACT CGGTGGCCAA
	GAACAAGCGC

13351	AGCTACTGGA TCAACGACGG TGGCGCCGCC GATGCCCAGG
	CCTGGTTCGA

13401	TGGCGCGCAG GAAGTGCCGG GCAGCTGGTG GCCGCAATGG
	GCCGGGTTCC

13451	TGACCCAGCA TGGCGGCAAG AAGGTCAAGC CCAAGGCCAA
	GCCCGGCAAC

13501	GCCCGCTACA CCGCGATCGA GGCGGCGCCC GGCCGTTACG
	TCAAAGCCAA

13551	GGGCTGAGCG GCCGCTGAGT AATTCTGATA TTAGAGGGAG
	CATTAATGTG

13601	TTGTTGTGAT GTGGTTTATA TGGGGAAATT AAATAAATGA
	TGTATGTACC

13651	TCTTGCCTAT GTAGGTTTGT GTGTTTTGTT TTGTTGTCTA
	GCTTTGGTTA

13701	TTAAGTAGTA GGGACGTTCG TTCGTGTCTC AAAAAAAGGG
	GTACTACCAC

13751	TCTGTAGTGT ATATGGATGC TGGAAATCAA TGTGTTTTGT
	ATTTGTTCAC

13801	CTCCATTGTT GAATTCAATG TCAAATGTGT TTTGCGTTGG
	TTATGTGTAA

13851	AATTACTATC TTTCTCGTCC GATGATCAAA GTTTTAAGCA
	ACAAAACCAA

13901	GGGTGAAATT TAAACTGTGC TTTGTTGAAG ATTCTTTTAT
	CATATTGAAA

13951	ATCAAATTAC TAGCAGCAGA TTTTACCTAG CATGAAATTT
	TATCAACAGT

14001	ACAGCACTCA CTAACCAAGT TCCAAACTAA GATGCGCCAT
	TAACATCAGC

14051	CAATAGGCAT TTTCAGCAAG GCGCGCCCGC GCCGATGTAT
	GTGACAACCC

14101	TCGGGATTGT TGATTTATTT CAAAACTAAG AGTTTTTGTC
	TTATTGTTCT

14151	CGTCTATTTT GGATATCAAT CTTAGTTTTA TATCTTTTCT
	AGTTCTCTAC

14201	GTGTTAAATG TTCAACACAC TAGCAATTTG GCCTGCCAGC
	GTATGGATTA

14251	TGGAACTATC AAGTCTGTGA CGCGCCGTAC GTAGTGTTTA
	TCTTTGTTGC

14301	TTTTCTGAAC AATTTATTTA CTATGTAAAT ATATTATCAA
	TGTTTAATCT

14351	ATTTTAATTT GCACATGAAT TTTCATTTTA TTTTTACTTT
	ACAAAACAAA

14401	TAAATATATA TGCAAAAAAA TTTACAAACG ATGCACGGGT
	TACAAACTAA

14451	TTTCATTAAA TGCTAATGCA GATTTTGTGA AGTAAAACTC
	CAATTATGAT

14501	GAAAAATACC ACCAACACCA CCTGCGAAAC TGTATCCCAA
	CTGTCCTTAA

14551	TAAAAATGTT AAAAAGTATA TTATTCTCAT TTGTCTCTCA
	TAATTTATGT

14601	ACCCCACTTT AATTTTTCTG ATGTACTAAA CCGAGGGCAA
	ACTGAAACCT

14651	GTTCCTCATG CAAAGCCCCT ACTCACCATG TATCATGTAC
	GTGTCATCAC

14701	CCAACAACTC CACTTTTGCT ATATAACAAC ACCCCCGTCA
	CACTCTCCCT

14751	CTCTAACACA CACCCCACTA ACAATTCCTT CACTTGCAGC
	ACTGTTGCAT

14801	CATCATCTTC ATTGCAAAAC CCTAAACTTC ACCTTCAACC
	GCGGCCGCAT

14851	GGCTTCTATG ATATCCTCTT CCGCTGTGAC AACAGTCAGC
	CGTGCCTCTA

14901	GGGGGCAATC CGCCGCAGTG GCTCCATTCG GCGGCCTCAA
	ATCCATGACT

14951	GGATTCCCAG TGAAGAAGGT CAACACTGAC ATTACTTCCA
	TTACAAGCAA

15001	TGGTGGAAGA GTAAAGTGCA TGCAGGTGTG GCCTCCAATT
	GGAAAGAAGA

15051	AGTTTGAGAC TCTTTCCTAT TTGCCACCAT TGACGAGAGA
	TTCTAGAGTG

15101	ACTCAGCGCA TTGCGTATGT GACCGGCGGC ATGGGTGGTA
	TCGGAACCGC

15151	CATTTGCCAG CGGCTGGCCA AGGATGGCTT TCGTGTGGTG
	GCCGGTTGCG

15201	GCCCCAACTC GCCGCGCCGC GAAAAGTGGC TGGAGCAGCA
	GAAGGCCCTG

15251	GGCTTCGATT TCATTGCCTC GGAAGGCAAT GTGGCTGACT
	GGGACTCGAC

15301	CAAGACCGCA TTCGACAAGG TCAAGTCCGA GGTCGGCGAG
	GTTGATGTGC

15351	TGATCAACAA CGCCGGTATC ACCCGCGACG TGGTGTTCCG
	CAAGATGACC

15401	CGCGCCGACT GGGATGCGGT GATCGACACC AACCTGACCT
	CGCTGTTCAA

15451	CGTCACCAAG CAGGTGATCG ACGGCATGGC CGACCGTGGC
	TGGGGCCGCA

15501	TCGTCAACAT CTCGTCGGTG AACGGGCAGA AGGGCCAGTT
	CGGCCAGACC

15551	AACTACTCCA CCGCCAAGGC CGGCCTGCAT GGCTTCACCA
	TGGCACTGGC

15601	GCAGGAAGTG GCCGCCAAGG GCGTGACCGT CAACACGGTC
	TCTCCGGGCT

15651	ATATCGCCAC CGACATGGTC AAGGCGATCC GCCAGGACGT
	GCTCGACAAG

15701	ATCGTCGCGA CGATCCCGGT CAAGCGCCTG GGCCTGCCGG
	AAGAGATCGC

15751	CTCGATCTGC GCCTGGTTGT CGTCGGAGGA GTCCGGTTTC
	TCGACCGGCG

15801	CCGACTTCTC GCTCAACGGC GGCCTGCATA TGGGCTGAGC
	GGCCGCTGAG

15851	TAATTCTGAT ATTAGAGGGA GCATTAATGT GTTGTTGTGA
	TGTGGTTTAT

15901	ATGGGGAAAT TAAATAAATG ATGTATGTAC CTCTTGCCTA
	TGTAGGTTTG

15951	TGTGTTTTGT TTTGTTGTCT AGCTTTGGTT ATTAAGTAGT
	AGGGACGTTC

16001	GTTCGTGTCT CAAAAAAAGG GGTACTACCA CTCTGTAGTG
	TATATGGATG

16051	CTGGAAATCA ATGTGTTTTG TATTTGTTCA CCTCCATTGT
	TGAATTCAAT

16101	GTCAAATGTG TTTTGCGTTG GTTATGTGTA AAATTACTAT
	CTTTCTCGTC

16151	CGATGATCAA AGTTTTAAGC AACAAAACCA AGGGTGAAAT
	TTAAACTGTG

16201	CTTTGTTGAA GATTCTTTTA TCATATTGAA AATCAAATTA
	CTAGCAGCAG

16251	ATTTTACCTA GCATGAAATT TTATCAACAG TACAGCACTC
	ACTAACCAAG

16301	TTCCAAACTA AGATGCGCCA TTAACATCAG CCAATAGGCA
	TTTTCAGCAA

16351	GGCGCGTAAG GGGATCCGTA CGTAAGTACG TACTCAAAAT
	GCCAACAAAT

16401	AAAAAAAAAG TTGCTTTAAT AATGCCAAAA CAAATTAATA
	AAACACTTAC

16451	AACACCGGAT TTTTTTTAAT TAAAATGTGC CATTTAGGAT
	AAATAGTTAA

16501	TATTTTTAAT AATTATTTAA AAAGCCGTAT CTACTAAAAT
	GATTTTTATT

16551	TGGTTGAAAA TATTAATATG TTTAAATCAA CACAATCTAT
	CAAAATTAAA

16601	CTAAAAAAAA AATAAGTGTA CGTGGTTAAC ATTAGTACAG
	TAATATAAGA

16651	GGAAAATGAG AAATTAAGAA ATTGAAAGCG AGTCTAATTT
	TTAAATTATG

16701	AACCTGCATA TATAAAAGGA AAGAAAGAAT CCAGGAAGAA
	AAGAAATGAA

16751	ACCATGCATG GTCCCCTCGT CATCACGAGT TTCTGCCATT
	TGCAATAGAA

16801	ACACTGAAAC ACCTTTCTCT TTGTCACTTA ATTGAGATGC
	CGAAGCCACC

16851	TCACACCATG AACTTCATGA GGTGTAGCAC CCAAGGCTTC
	CATAGCCATG

16901	CATACTGAAG AATGTCTCAA GCTCAGCACC CTACTTCTGT
	GACGTGTCCC

16951	TCATTCACCT TCCTCTCTTC CCTATAAATA ACCACGCCTC
	AGGTTCTCCG

17001	CTTCACAACT CAAACATTCT CTCCATTGGT CCTTAAACAC
	TCATCAGTCA

17051	TCACCGCGGC CGCGGAATTC ATGGCTTCTA TGATATCCTC
	TTCCGCTGTG

17101	ACAACAGTCA GCCGTGCCTC TAGGGGGCAA TCCGCCGCAG
	TGGCTCCATT

17151	CGGCGGCCTC AAATCCATGA CTGGATTCCC AGTGAAGAAG
	GTCAACACTG

17201	ACATTACTTC CATTACAAGC AATGGTGGAA GAGTAAAGTG
	CATGCAGGTG

17251	TGGCCTCCAA TTGGAAAGAA GAAGTTTGAG ACTCTTTCCT
	ATTTGCCACC

17301	ATTGACGAGA GATTCTAGAG TGACTGACGT TGTCATCGTA
	TCCGCCGCCC

17351	GCACCGCGGT CGGCAAGTTT GGCGGCTCGC TGGCCAAGAT
	CCCGGCACCG

17401	GAACTGGGTG CCGTGGTCAT CAAGGCCGCG CTGGAGCGCG
	CCGGCGTCAA

17451	GCCGGAGCAG GTGAGCGAAG TCATCATGGG CCAGGTGCTG
	ACCGCCGGTT

17501	CGGGCCAGAA CCCCGCACGC CAGGCCGCGA TCAAGGCCGG
	CCTGCCCGCG

17551	ATGGTGCCGG CCATGACCAT CAACAAGGTG TGCGGCTCGG
	GCCTGAAGGC

17601	CGTGATGCTG GCCGCCAACG CGATCATGGC GGGCGACGCC
	GAGATCGTGG

17651	TGGCCGGCGG CCAGGAAAAC ATGAGCGCCG CCCCGCACGT
	GCTGCCGGGC

17701	TCGCGCGATG GTTTCCGCAT GGGCGATGCC AAGCTGGTCG
	ACACCATGAT

17751	CGTCGACGGC CTGTGGGACG TGTACAACCA GTACCACATG
	GGCATCACCG

17801	CCGAGAACGT GGCCAAGGAA TACGGCATCA CACGCGAGGC
	GCAGGATGAG

17851	TTCGCCGTCG GCTCGCAGAA CAAGGCCGAA GCCGCGCAGA
	AGGCCGGCAA

17901	GTTTGACGAA GAGATCGTCC CGGTGCTGAT CCCGCAGCGC
	AAGGGCGACC

17951	CGGTGGCCTT CAAGACCGAC GAGTTCGTGC GCCAGGGCGC
	CACGCTGGAC

18001	AGCATGTCCG GCCTCAAGCC CGCCTTCGAC AAGGCCGGCA
	CGGTGACCGC

18051	GGCCAACGCC TCGGGCCTGA ACGACGGCGC CGCCGCGGTG
	GTGGTGATGT

18101	CGGCGGCCAA GGCCAAGGAA CTGGGCCTGA CCCCGCTGGC
	CACGATCAAG

18151	AGCTATGCCA ACGCCGGTGT CGATCCCAAG GTGATGGGCA
	TGGGCCCGGT

18201	GCCGGCCTCC AAGCGCGCCC TGTCGCGCGC CGAGTGGACC
	CCGCAAGACC

18251	TGGACCTGAT GGAGATCAAC GAGGCCTTTG CCGCGCAGGC
	GCTGGCGGTG

18301	CACCAGCAGA TGGGCTGGGA CACCTCCAAG GTCAATGTGA
	ACGGCGGCGC

18351	CATCGCCATC GGCCACCCGA TCGGCGCGTC GGGCTGCCGT
	ATCCTGGTGA

18401	CGCTGCTGCA CGAGATGAAG CGCCGTGACG CGAAGAAGGG
	CCTGGCCTCG

18451	CTGTGCATCG GCGGCGGCAT GGGCGTGGCG CTGGCAGTCG
	AGCGCAAATA

18501	ACTCGAGGCG GCCGCAGCCC TTTTTGTATG TGCTACCCCA
	CTTTTGTCTT

18551	TTTGGCAATA GTGCTAGCAA CCAATAAATA ATAATAATAA
	TAATGAATAA

18601	GAAAACAAAG GCTTTAGCTT GCCTTTTGTT CACTGTAAAA
	TAATAATGTA

18651	AGTACTCTCT ATAATGAGTC ACGAAACTTT TGCGGGAATA
	AAAGGAGAAA

18701	TTCCAATGAG TTTTCTGTCA AATCTTCTTT TGTCTCTCTC
	TCTCTCTCTT

18751	TTTTTTTTTT CTTTCTTCTG AGCTTCTTGC AAAACAAAAG
	GCAAACAATA

18801	ACGATTGGTC CAATGATAGT TAGCTTGATC GATGATATCT
	TTAGGAAGTG

18851	TTGGCAGGAC AGGACATGAT GTAGAAGACT AAAATTGAAA
	GTATTGCAGA

18901	CCCAATAGTT GAAGATTAAC TTTAAGAATG AAGACGTCTT
	ATCAGGTTCT

18951	TCATGACTTA AGCTTTAAGA GGAGTCCACC ATGGTAGATC
	TGACTAGTAA

19001	CGGCCGCCAG TGTGCTGGAA TTCTGCAGAT GTGGAGCACG
	ACACTCTCGT

19051	CTACTCCAAG AATATCAAAG ATACAGTCTC AGAAGACCAA
	AGGGCTATTG

19101	AGACTTTTCA ACAAAGGGTA ATATCGGGAA ACCTCCTCGG
	ATTCCATTGC

19151	CCAGCTATCT GTCACTTCAT CAAAAGGACA GTAGAAAAGG
	AAGGTGGCAC

19201	CTACAAATGC CATCATTGCG ATAAAGGAAA GGCTATCGTT
	CAAGATGCCT

19251	CTGCCGACAG TGGTCCCAAA GATGGACCCC CACCCACGAG
	GAGCATCGTG

19301	GAAAAAGAAG ACGTTCCAAC CACGTCTTCA AAGCAAGTGG
	ATTGATGTGA

19351	TAACATGGTG GAGCACGACA CTCTCGTCTA CTCCAAGAAT
	ATCAAAGATA

19401	CAGTCTCAGA AGACCAAAGG GCTATTGAGA CTTTTCAACA
	AAGGGTAATA

19451	TCGGGAAACC TCCTCGGATT CCATTGCCCA GCTATCTGTC
	ACTTCATCAA

19501	AAGGACAGTA GAAAAGGAAG GTGGCACCTA CAAATGCCAT
	CATTGCGATA

19551	AAGGAAAGGC TATCGTTCAA GATGCCTCTG CCGACAGTGG
	TCCCAAAGAT

19601	GGACCCCCAC CCACGAGGAG CATCGTGGAA AAAGAAGACG
	TTCCAACCAC

19651	GTCTTCAAAG CAAGTGGATT GATGTGATAT CTCCACTGAC
	GTAAGGGATG

19701	ACGCACAATC CCACTATCCT TCGCAAGACC TTCCTCTATA
	TAAGGAAGTT

19751	CATTTCATTT GGAGAGGACA CGCTGAAATC ACCAGTCTCT
	CTCTACAAAT

19801	CTATCTCTCT CGAGCTTTCG CAGATCTGTC GATCGACCAT
	GGACTCCAAA

19851	GAATCATTAA CTCCTGGTAG AGAAGAAAAC CCCAGCAGTG
	TGCTTGCTCA

19901	GGAGAGGGGA GATGTGATGG ACTTCTATAA AACCCTAAGA
	GGAGGAGCTA

19951	CTGTGAAGGT TTCTGCGTCT TCACCCTCAC TGGCTGTCGC
	TTCTCAATCA

20001	GACTCCAAGC AGCGAAGACT TTTGGTTGAT TTTCCAAAAG
	GCTCAGTAAG

20051	CAATGCGCAG CAGCCAGATC TGTCCAAAGC AGTTTCACTC
	TCAATGGGAC

20101	TGTATATGGG AGAGACAGAA ACAAAAGTGA TGGGAAATGA
	CCTGGGATTC

20151	CCACAGCAGG GCCAAATCAG CCTTTCCTCG GGGGAAACAG
	ACTTAAAGCT

20201	TTTGGAAGAA AGCATTGCAA ACCTCAATAG GTCGACCAGT
	GTTCCAGAGA

20251	ACCCCAAGAG TTCAGCATCC ACTGCTGTGT CTGCTGCCCC
	CACAGCTAGT

20301	TCTGCGGCCC CCCCGACCGA TGTCAGCCTG GGGGACGAGC
	TCCACTTAGA

20351	CGGCGAGGAC GTGGCGATGG CGCATGCCGA CGCGCTAGAC
	GATTTCGATC

20401	TGGACATGTT GGGGGACGGG GATTCCCCGG GTCCGGGATT
	TACCCCCCAC

20451	GACTCCGCCC CCTACGGCGC TCTGGATATG GCCGACTTCG
	AGTTTGAGCA

20501	GATGTTTACC GATGCCCTTG GAATTGACGA GTACGGTGGG
	ACTAGCTCCA

20551	GCTCCTCAAC AGCAACAACA GGACCACCTC CCAAACTCTG
	CCTGGTGTGC

20601	TCTGATGAAG CTTCAGGATG TCATTATGGA GTCTTAACTT
	GTGGAAGCTG

20651	TAAAGTTTTC TTCAAAAGAG CAGTGGAAGG ACAGCACAAT
	TACCTATGTG

20701	CTGGAAGGAA TGATTGCATC ATCGATAAAA TTCGAAGAAA
	AAACTGCCCA

20751	GCATGCCGCT ATCGAAAATG TCTTCAGGCT GGAATGAACC
	TGGAAGCTCG

20801	AAAAACAAAG AAAAAAATAA AAGGAATTGC TCGACAAAGG
	CCCGAGTGCG

20851	TGGTGCCGGA GAACCAGTGT GCAATGAAAC GGAAAGAGAA
	AAAGGCGCAG

20901	AGGGAAAAAG ACAAATTGCC CGTCAGTACG ACGACAGTAG
	ACGATCACAT

20951	GCCTCCCATC ATGCAATGTG ACCCTCCGCC CCCAGAGGCC
	GCTAGAATTC

21001	TGGAATGTTT GCAGCACGAG GTGGTGCCAC GATTCCTGAA
	TGAGAAGCTA

21051	ATGGAACAGA ACAGATTGAA GAACGTGCCC CCCCTCACTG
	CCAATCAGAA

21101	GTCGTTGATC GCAAGGCTCG TGTGGTACCA GGAAGGCTAT
	GAACAACCTT

21151	CCGAGGAAGA CCTGAAGAGG GTTACACAGT CGGACGAGGA
	CGACGAAGAC

21201	TCGGATATGC CGTTCCGTCA GATTACCGAG ATGACGATTC
	TCACAGTGCA

21251	GCTCATCGTA GAATTCGCTA AGGGCCTCCC GGGCTTCGCC
	AAGATCTCGC

21301	AGTCGGACCA GATCACGTTA TTAAAGGCGT GCTCAAGTGA
	GGTGATGATG

21351	CTCCGAGTGG CTCGGCGGTA TGACGCGGCC ACCGACAGCG
	TACTGTTCGC

21401	GAACAACCAG GCGTACACTC GCGACAACTA CCGCAAGGCA
	GGCATGGCGT

21451	ACGTCATCGA GGACCTGCTG CACTTCTGTC GGTGCATGTA
	CTCCATGATG

21501	ATGGATAACG TGCATTATGC GCTGCTTACA GCCATTGTCA
	TCTTCTCAGA

21551	CCGGCCCGGG CTTGAGCAAC CCCTGTTGGT GGAGGAGATC
	CAGAGATATT

21601	ACCTGAACAC GCTACGGGTG TACATCCTGA ACCAGAACAG
	CGCGTCGCCC

21651	CGCTGCGCCG TCATCTTCGG CAAGATCCTG GGCATACTGA
	CGGAGATCCG

21701	CACGCTGGGC ATGCAGAACT CCAACATGTG CATCTCCCTC
	AAGCTGAAGA

21751	ACAGGAAGCT GCCGCCGTTC CTCGAGGAGA TCTGGGACGT
	GGCGGACGTG

21801	GCGACGACGG CGACGCCGGT GGCGGCGGAG GCGCCGGCGC
	TCTAGCCCCC

21851	GCGCCGCCCG CCCGGCCGCG CGCACGTCTA GCGCGCCTCA
	GGAGAGAACG

21901	CTCATAGACT GGCTAGTTTT AGTGAAGTGC ACGGACACTG
	ACGTCGGACG

21951	TGATCAACCT ATTTATAAGG ACTGCGAATT TTACCACTTA
	AGAGGGCACA

22001	CCCGTACCCG ATTTCGTACG GGAATTCCTG CAGCCCGGGG
	GATCCTTAAT

22051	TAACTCGAGG AATTCATCGA TTCCGCGGGT ACCGAGCTCG
	ATCCGTCGAC

22101	CTGCAGATCG TTCAAACATT TGGCAATAAA GTTTCTTAAG
	ATTGAATCCT

22151	GTTGCCGGTC TTGCGATGAT TATCATATAA TTTCTGTTGA
	ATTACGTTAA

22201	GCATGTAATA ATTAACATGT AATGCATGAC GTTATTTATG
	AGATGGGTTT

22251	TTATGATTAG AGTCCCGCAA TTATACATTT AATACGCGAT
	AGAAAACAAA

22301	ATATAGCGCG CAAACTAGGA TAAATTATCG CGCGCGGTGT
	CATCTATGTT

22351	ACTAGATCTG GCGCGCCCCT AGGTCTAGAG TCGACTGTTT
	AAACG

Vector: pPhaC-RNAi/35S

(SEQ ID NO: 4)

1	AAATAGAAGG TAATTATCCA AGATGTAGCA TCAAGAATCC
	AATGTTTACG

51	GGAAAAACTA TGGAAGTATT ATGTGAGCTC AGCAAGAAGC
	AGATCAATAT

101	GCGGCACATA TGCAACCTAT GTTCAAAAAT GAAGAATGTA
	CAGATACAAG

151	ATCCTATACT GCCAGAATAC GAAGAAGAAT ACGTAGAAAT
	TGAAAAAGAA

201	GAACCAGGCG AAGAAAAGAA TCTTGAAGAC GTAAGCACTG
	ACGACAACAA

251	TGAAAAGAAG AAGATAAGGT CGGTGATTGT GAAAGAGACA
	TAGAGGACAC

301	ATGTAAGGTG GAAAATGTAA GGGCGGAAAG TAACCTTATC
	ACAAAGGAAT

351	CTTATCCCCC ACTACTTATC CTTTTATATT TTTCCGTGTC
	ATTTTTGCCC

401	TTGAGTTTTC CTATATAAGG AACCAAGTTC GGCATTTGTG
	AAAACAAGAA

451	AAAATTGGTG TAAGCTATTT TCTTTGAAGT ACTGAGGATA
	CAACTTCAGA

501	GAAATTTGTA AGAAAGTGGA TCGAAACCAT GGCCTCCTCC
	GAGAACGTCA

551	TCACCGAGTT CATGCGCTTC AAGGTGCGCA TGGAGGGCAC
	CGTGAACGGC

601	CACGAGTTCG AGATCGAGGG CGAGGGCGAG GGCCGCCCCT
	ACGAGGGCCA

651	CAACACCGTG AAGCTGAAGG TGACCAAGGG CGGCCCCCTG
	CCCTTCGCCT

701	GGGACATCCT GTCCCCCCAG TTCCAGTACG GCTCCAAGGT
	GTACGTGAAG

751	CACCCCGCCG ACATCCCCGA CTACAAGAAG CTGTCCTTCC
	CCGAGGGCTT

801	CAAGTGGGAG CGCGTGATGA ACTTCGAGGA CGGCGGCGTG
	GCGACCGTGA

851	CCCAGGACTC CTCCCTGCAG GACGGCTGCT TCATCTACAA
	GGTGAAGTTC

901	ATCGGCGTGA ACTTCCCCTC CGACGGCCCC GTGATGCAGA
	AGAAGACCAT

951	GGGCTGGGAG GCCTCCACCG AGCGCCTGTA CCCCCGCGAC
	GGCGTGCTGA

1001	AGGGCGAGAC CCACAAGGCC CTGAAGCTGA AGGACGGCGG
	CCACTACCTG

1051	GTGGAGTTCA AGTCCATCTA CATGGCCAAG AAGCCCGTGC
	AGCTGCCCGG

1101	CTACTACTAC GTGGACGCCA AGCTGGACAT CACCTCCCAC
	AACGAGGACT

1151	ACACCATCGT GGAGCAGTAC GAGCGCACCG AGGGCCGCCA
	CCACCTGTTC

1201	CTGGTACCAA TGAGCTCTGT CCAACAGTCT CAGGGTTAAT
	GTCTATGTAT

1251	CTTAAATAAT GTTGTCGGCG ATCGTTCAAA CATTTGGCAA
	TAAAGTTTCT

1301	TAAGATTGAA TCCTGTTGCC GGTCTTGCGA TGATTATCAT
	ATAATTTCTG

1351	TTGAATTACG TTAAGCATGT AATAATTAAC ATGTAATGCA
	TGACGTTATT

1401	TATGAGATGG GTTTTTATGA TTAGAGTCCC GCAATTATAC
	ATTTAATACG

1451	CGATAGAAAA CAAAATATAG CGCGCAAACT AGGATAAATT
	ATCGCGCGCG

1501	GTGTCATCTA TGTTACTAGA TCGGGAATTA AACTATCAGT
	GTTTGACAGG

1551	ATATATTGGC GGGTAAACCT AAGAGAAAAG AGCGTTTATT
	AGAATAACGG

1601	ATATTTAAAA GGGCGTGAAA AGGTTTATCC GTTCGTCCAT
	TTGTATGTGC

1651	ATGCCAACCA CAGGGTTCCC CTCGGGATCA AAGTACTTTG
	ATCCAACCCC

1701	TCCGCTGCTA TAGTGCAGTC GGCTTCTGAC GTTCAGTGCA
	GCCGTCTTCT

1751	GAAAACGACA TGTCGCACAA GTCCTAAGTT ACGCGACAGG
	CTGCCGCCCT

1801	GCCCTTTTCC TGGCGTTTTC TTGTCGCGTG TTTTAGTCGC
	ATAAAGTAGA

1851	ATACTTGCGA CTAGAACCGG AGACATTACG CCATGAACAA
	GAGCGCCGCC

1901	GCTGGCCTGC TGGGCTATGC CCGCGTCAGC ACCGACGACC
	AGGACTTGAC

1951	CAACCAACGG GCCGAACTGC ACGCGGCCGG CTGCACCAGG
	CTGTTTTCCG

2001	AGAAGATCAC CGGCACCAGG CGCGACCGCC CGGAGCTGGC
	CAGGATGCTT

2051	GACCACCTAC GCCCTGGCGA CGTTGTGACA GTGACCAGGC
	TAGACCGCCT

2101	GGCCCGCAGC ACCCGCGACC TACTGGACAT TGCCGAGCGC
	ATCCAGGAGG

2151	CCGGCGCGGG CCTGCGTAGC CTGGCAGAGC CGTGGGCCGA
	CACCACCACG

2201	CCGGCCGGCC GCATGGTGTT GACCGTGTTC GCCGGCATTG
	CCGAGTTCGA

2251	GCGTTCCCTA ATCATCGACC GCACCCGGAG CGGGCGCGAG
	GCCGCCAAGG

2301	CCCGAGGCGT GAAGTTTGGC CCCCGCCCTA CCCTCACCCC
	GGCACAGATC

2351	GCGCACGCCC GCGAGCTGAT CGACCAGGAA GGCCGCACCG
	TGAAAGAGGC

2401	GGCTGCACTG CTTGGCGTGC ATCGCTCGAC CCTGTACCGC
	GCACTTGAGC

2451	GCAGCGAGGA AGTGACGCCC ACCGAGGCCA GGCGGCGCGG
	TGCCTTCCGT

2501	GAGGACGCAT TGACCGAGGC CGACGCCCTG GCGGCCGCCG
	AGAATGAACG

2551	CCAAGAGGAA CAAGCATGAA ACCGCACCAG GACGGCCAGG
	ACGAACCGTT

2601	TTTCATTACC GAAGAGATCG AGGCGGAGAT GATCGCGGCC
	GGGTACGTGT

2651	TCGAGCCGCC CGCGCACGTC TCAACCGTGC GGCTGCATGA
	AATCCTGGCC

2701	GGTTTGTCTG ATGCCAAGCT GGCGGCCTGG CCGGCCAGCT
	TGGCCGCTGA

2751	AGAAACCGAG CGCCGCCGTC TAAAAAGGTG ATGTGTATTT
	GAGTAAAACA

2801	GCTTGCGTCA TGCGGTCGCT GCGTATATGA TGCGATGAGT
	AAATAAACAA

2851	ATACGCAAGG GGAACGCATG AAGGTTATCG CTGTACTTAA
	CCAGAAAGGC

2901	GGGTCAGGCA AGACGACCAT CGCAACCCAT CTAGCCCGCG
	CCCTGCAACT

2951	CGCCGGGGCC GATGTTCTGT TAGTCGATTC CGATCCCCAG
	GGCAGTGCCC

3001	GCGATTGGGC GGCCGTGCGG GAAGATCAAC CGCTAACCGT
	TGTCGGCATC

3051	GACCGCCCGA CGATTGACCG CGACGTGAAG GCCATCGGCC
	GGCGCGACTT

3101	CGTAGTGATC GACGGAGCGC CCCAGGCGGC GGACTTGGCT
	GTGTCCGCGA

3151	TCAAGGCAGC CGACTTCGTG CTGATTCCGG TGCAGCCAAG
	CCCTTACGAC

3201	ATATGGGCCA CCGCCGACCT GGTGGAGCTG GTTAAGCAGC
	GCATTGAGGT

3251	CACGGATGGA AGGCTACAAG CGGCCTTTGT CGTGTCGCGG
	GCGATCAAAG

3301	GCACGCGCAT CGGCGGTGAG GTTGCCGAGG CGCTGGCCGG
	GTACGAGCTG

3351	CCCATTCTTG AGTCCCGTAT CACGCAGCGC GTGAGCTACC
	CAGGCACTGC

3401	CGCCGCCGGC ACAACCGTTC TTGAATCAGA ACCCGAGGGC
	GACGCTGCCC

3451	GCGAGGTCCA GGCGCTGGCC GCTGAAATTA AATCAAAACT
	CATTTGAGTT

3501	AATGAGGTAA AGAGAAAATG AGCAAAAGCA CAAACACGCT
	AAGTGCCGGC

3551	CGTCCGAGCG CACGCAGCAG CAAGGCTGCA ACGTTGGCCA
	GCCTGGCAGA

3601	CACGCCAGCC ATGAAGCGGG TCAACTTTCA GTTGCCGGCG
	GAGGATCACA

3651	CCAAGCTGAA GATGTACGCG GTACGCCAAG GCAAGACCAT
	TACCGAGCTG

3701	CTATCTGAAT ACATCGCGCA GCTACCAGAG TAAATGAGCA
	AATGAATAAA

3751	TGAGTAGATG AATTTTAGCG GCTAAAGGAG GCGGCATGGA
	AAATCAAGAA

3801	CAACCAGGCA CCGACGCCGT GGAATGCCCC ATGTGTGGAG
	GAACGGGCGG

3851	TTGGCCAGGC GTAAGCGGCT GGGTTGTCTG CCGGCCCTGC
	AATGGCACTG

3901	GAACCCCCAA GCCCGAGGAA TCGGCGTGAC GGTCGCAAAC
	CATCCGGCCC

3951	GGTACAAATC GGCGCGGCGC TGGGTGATGA CCTGGTGGAG
	AAGTTGAAGG

4001	CCGCGCAGGC CGCCCAGCGG CAACGCATCG AGGCAGAAGC
	ACGCCCCGGT

4051	GAATCGTGGC AAGCGGCCGC TGATCGAATC CGCAAAGAAT
	CCCGGCAACC

4101	GCCGGCAGCC GGTGCGCCGT CGATTAGGAA GCCGCCCAAG
	GGCGACGAGC

4151	AACCAGATTT TTTCGTTCCG ATGCTCTATG ACGTGGGCAC
	CCGCGATAGT

4201	CGCAGCATCA TGGACGTGGC CGTTTTCCGT CTGTCGAAGC
	GTGACCGACG

4251	AGCTGGCGAG GTGATCCGCT ACGAGCTTCC AGACGGGCAC
	GTAGAGGTTT

4301	CCGCAGGGCC GGCCGGCATG GCCAGTGTGT GGGATTACGA
	CCTGGTACTG

4351	ATGGCGGTTT CCCATCTAAC CGAATCCATG AACCGATACC
	GGGAAGGGAA

4401	GGGAGACAAG CCCGGCCGCG TGTTCCGTCC ACACGTTGCG
	GACGTACTCA

4451	AGTTCTGCCG GCGAGCCGAT GGCGGAAAGC AGAAAGACGA
	CCTGGTAGAA

4501	ACCTGCATTC GGTTAAACAC CACGCACGTT GCCATGCAGC
	GTACGAAGAA

4551	GGCCAAGAAC GGCCGCCTGG TGACGGTATC CGAGGGTGAA
	GCCTTGATTA

4601	GCCGCTACAA GATCGTAAAG AGCGAAACCG GGCGGCCGGA
	GTACATCGAG

4651	ATCGAGCTAG CTGATTGGAT GTACCGCGAG ATCACAGAAG
	GCAAGAACCC

4701	GGACGTGCTG ACGGTTCACC CCGATTACTT TTTGATCGAT
	CCCGGCATCG

4751	GCCGTTTTCT CTACCGCCTG GCACGCCGCG CCGCAGGCAA
	GGCAGAAGCC

4801	AGATGGTTGT TCAAGACGAT CTACGAACGC AGTGGCAGCG
	CCGGAGAGTT

4851	CAAGAAGTTC TGTTTCACCG TGCGCAAGCT GATCGGGTCA
	AATGACCTGC

4901	CGGAGTACGA TTTGAAGGAG GAGGCGGGGC AGGCTGGCCC
	GATCCTAGTC

4951	ATGCGCTACC GCAACCTGAT CGAGGGCGAA GCATCCGCCG
	GTTCCTAATG

5001	TACGGAGCAG ATGCTAGGGC AAATTGCCCT AGCAGGGGAA
	AAAGGTCGAA

5051	AAGGTCTCTT TCCTGTGGAT AGCACGTACA TTGGGAACCC
	AAAGCCGTAC

5101	ATTGGGAACC GGAACCCGTA CATTGGGAAC CCAAAGCCGT
	ACATTGGGAA

5151	CCGGTCACAC ATGTAAGTGA CTGATATAAA AGAGAAAAAA
	GGCGATTTTT

5201	CCGCCTAAAA CTCTTTAAAA CTTATTAAAA CTCTTAAAAC
	CCGCCTGGCC

5251	TGTGCATAAC TGTCTGGCCA GCGCACAGCC GAAGAGCTGC
	AAAAAGCGCC

5301	TACCCTTCGG TCGCTGCGCT CCCTACGCCC CGCCGCTTCG
	CGTCGGCCTA

5351	TCGCGGCCGC TGGCCGCTCA AAAATGGCTG GCCTACGGCC
	AGGCAATCTA

5401	CCAGGGCGCG GACAAGCCGC GCCGTCGCCA CTCGACCGCC
	GGCGCCCACA

5451	TCAAGGCACC CTGCCTCGCG CGTTTCGGTG ATGACGGTGA
	AAACCTCTGA

5501	CACATGCAGC TCCCGGAGAC GGTCACAGCT TGTCTGTAAG
	CGGATGCCGG

5551	GAGCAGACAA GCCCGTCAGG GCGCGTCAGC GGGTGTTGGC
	GGGTGTCGGG

5601	GCGCAGCCAT GACCCAGTCA CGTAGCGATA GCGGAGTGTA
	TACTGGCTTA

5651	ACTATGCGGC ATCAGAGCAG ATTGTACTGA GAGTGCACCA
	TATGCGGTGT

5701	GAAATACCGC ACAGATGCGT AAGGAGAAAA TACCGCATCA
	GGCGCTCTTC

5751	CGCTTCCTCG CTCACTGACT CGCTGCGCTC GGTCGTTCGG
	CTGCGGCGAG

5801	CGGTATCAGC TCACTCAAAG GCGGTAATAC GGTTATCCAC
	AGAATCAGGG

5851	GATAACGCAG GAAAGAACAT GTGAGCAAAA GGCCAGCAAA
	AGGCCAGGAA

5901	CCGTAAAAAG GCCGCGTTGC TGGCGTTTTT CCATAGGCTC
	CGCCCCCCTG

5951	ACGAGCATCA CAAAAATCGA CGCTCAAGTC AGAGGTGGCG
	AAACCCGACA

6001	GGACTATAAA GATACCAGGC GTTTCCCCCT GGAAGCTCCC
	TCGTGCGCTC

6051	TCCTGTTCCG ACCCTGCCGC TTACCGGATA CCTGTCCGCC
	TTTCTCCCTT

6101	CGGGAAGCGT GGCGCTTTCT CATAGCTCAC GCTGTAGGTA
	TCTCAGTTCG

6151	GTGTAGGTCG TTCGCTCCAA GCTGGGCTGT GTGCACGAAC
	CCCCCGTTCA

6201	GCCCGACCGC TGCGCCTTAT CCGGTAACTA TCGTCTTGAG
	TCCAACCCGG

6251	TAAGACACGA CTTATCGCCA CTGGCAGCAG CCACTGGTAA
	CAGGATTAGC

6301	AGAGCGAGGT ATGTAGGCGG TGCTACAGAG TTCTTGAAGT
	GGTGGCCTAA

6351	CTACGGCTAC ACTAGAAGGA CAGTATTTGG TATCTGCGCT
	CTGCTGAAGC

6401	CAGTTACCTT CGGAAAAAGA GTTGGTAGCT CTTGATCCGG
	CAAACAAACC

6451	ACCGCTGGTA GCGGTGGTTT TTTTGTTTGC AAGCAGCAGA
	TTACGCGCAG

6501	AAAAAAAGGA TCTCAAGAAG ATCCTTTGAT CTTTTCTACG
	GGGTCTGACG

6551	CTCAGTGGAA CGAAAACTCA CGTTAAGGGA TTTTGGTCAT
	GCATTCTAGG

6601	TACTAAAACA ATTCATCCAG TAAAATATAA TATTTTATTT
	TCTCCCAATC

6651	AGGCTTGATC CCCAGTAAGT CAAAAAATAG CTCGACATAC
	TGTTCTTCCC

6701	CGATATCCTC CCTGATCGAC CGGACGCAGA AGGCAATGTC
	ATACCACTTG

6751	TCCGCCCTGC CGCTTCTCCC AAGATCAATA AAGCCACTTA
	CTTTGCCATC

6801	TTTCACAAAG ATGTTGCTGT CTCCCAGGTC GCCGTGGGAA
	AAGACAAGTT

6851	CCTCTTCGGG CTTTTCCGTC TTTAAAAAAT CATACAGCTC
	GCGCGGATCT

6901	TTAAATGGAG TGTCTTCTTC CCAGTTTTCG CAATCCACAT
	CGGCCAGATC

6951	GTTATTCAGT AAGTAATCCA ATTCGGCTAA GCGGCTGTCT
	AAGCTATTCG

7001	TATAGGGACA ATCCGATATG TCGATGGAGT GAAAGAGCCT
	GATGCACTCC

7051	GCATACAGCT CGATAATCTT TTCAGGGCTT TGTTCATCTT
	CATACTCTTC

7101	CGAGCAAAGG ACGCCATCGG CCTCACTCAT GAGCAGATTG
	CTCCAGCCAT

7151	CATGCCGTTC AAAGTGCAGG ACCTTTGGAA CAGGCAGCTT
	TCCTTCCAGC

7201	CATAGCATCA TGTCCTTTTC CCGTTCCACA TCATAGGTGG
	TCCCTTTATA

7251	CCGGCTGTCC GTCATTTTTA AATATAGGTT TTCATTTTCT
	CCCACCAGCT

7301	TATATACCTT AGCAGGAGAC ATTCCTTCCG TATCTTTTAC
	GCAGCGGTAT

7351	TTTTCGATCA GTTTTTTCAA TTCCGGTGAT ATTCTCATTT
	TAGCCATTTA

7401	TTATTTCCTT CCTCTTTTCT ACAGTATTTA AAGATACCCC
	AAGAAGCTAA

7451	TTATAACAAG ACGAACTCCA ATTCACTGTT CCTTGCATTC
	TAAAACCTTA

7501	AATACCAGAA AACAGCTTTT TCAAAGTTGT TTTCAAAGTT
	GGCGTATAAC

7551	ATAGTATCGA CGGAGCCGAT TTTGAAACCG CGGTGATCAC
	AGGCAGCAAC

7601	GCTCTGTCAT CGTTACAATC AACATGCTAC CCTCCGCGAG
	ATCATCCGTG

7651	TTTCAAACCC GGCAGCTTAG TTGCCGTTCT TCCGAATAGC
	ATCGGTAACA

7701	TGAGCAAAGT CTGCCGCCTT ACAACGGCTC TCCCGCTGAC
	GCCGTCCCGG

7751	ACTGATGGGC TGCCTGTATC GAGTGGTGAT TTTGTGCCGA
	GCTGCCGGTC

7801	GGGGAGCTGT TGGCTGGCTG GTGGCAGGAT ATATTGTGGT
	GTAAACAAAT

7851	TGACGCTTAG ACAACTTAAT AACACATTGC GGACGTTTTT
	AATGTACTGA

7901	ATTAACGCCG AATTAATTCC TAGGCCACCA TGTTGGGCCC
	GGGGCGCGCC

7951	GTACGTAGTG TTTATCTTTG TTGCTTTTCT GAACAATTTA
	TTTACTATGT

8001	AAATATATTA TCAATGTTTA ATCTATTTTA ATTTGCACAT
	GAATTTTCAT

8051	TTTATTTTTA CTTTACAAAA CAAATAAATA TATATGCAAA
	AAAATTTACA

8101	AACGATGCAC GGGTTACAAA CTAATTTCAT TAAATGCTAA
	TGCAGATTTT

8151	GTGAAGTAAA ACTCCAATTA TGATGAAAAA TACCACCAAC
	ACCACCTGCG

8201	AAACTGTATC CCAACTGTCC TTAATAAAAA TGTTAAAAAG
	TATATTATTC

8251	TCATTTGTCT GTCATAATTT ATGTACCCCA CTTTAATTTT
	TCTGATGTAC

8301	TAAACCGAGG GCAAACTGAA ACCTGTTCCT CATGCAAAGC
	CCCTACTCAC

8351	CATGTATCAT GTACGTGTCA TCACCCAACA ACTCCACTTT
	TGCTATATAA

8401	CAACACCCCC GTCACACTCT CCCTCTCTAA CACACACCCC
	ACTAACAATT

8451	CCTTCACTTG CAGCACTGTT GCATCATCAT CTTCATTGCA
	AAACCCTAAA

8501	CTTCACCTTC AACCGCGGCC GCATGGCTTC TATGATATCC
	TCTTCCGCTG

8551	TGACAACAGT CAGCCGTGCC TCTAGGGGGC AATCCGCCGC
	AGTGGCTCCA

8601	TTCGGCGGCC TCAAATCCAT GACTGGATTC CCAGTGAAGA
	AGGTCAACAC

8651	TGACATTACT TCCATTACAA GCAATGGTGG AAGAGTAAAG
	TGCATGCAGG

8701	TGTGGCCTCC AATTGGAAAG AAGAAGTTTG AGACTCTTTC
	CTATTTGCCA

8751	CCATTGACGA GAGATTCTAG AGTGAGTAAC AAGAACAACG
	ATGAGCTGCA

8801	GTGGCAATCC TGGTTCAGCA AGGCGCCCAC CACCGAGGCG
	AACCCGATGG

8851	CCACCATGTT GCAGGATATC GGCGTTGCGC TCAAACCGGA
	AGCGATGGAG

8901	CAGCTGAAAA ACGATTATCT GCGTGACTTC ACCGCGTTGT
	GGCAGGATTT

8951	TTTGGCTGGC AAGGCGCCAG CCGTCAGCGA CCGCCGCTTC
	AGCTCGGCAG

9001	CCTGGCAGGG CAATCCGATG TCGGCCTTCA ATGCCGCATC
	TTACCTGCTC

9051	AACGCCAAAT TCCTCAGTGC CATGGTGGAG GCGGTGGACA
	CCGCACCCCA

9101	GCAAAAGCAG AAAATACGCT TTGCCGTGCA GCAGGTGATT
	GATGCCATGT

9151	CGCCCGCGAA CTTCCTCGCC ACCAACCCGG AAGCGCAGCA
	AAAACTGATT

9201	GAAACCAAGG GCGAGAGCCT GACGCGTGGC CTGGTCAATA
	TGCTGGGCGA

9251	TATCAACAAG GGCCATATCT CGCTGTCGGA CGAATCGGCC
	TTTGAAGTGG

9301	GCCGCAACCT GGCCATTACC CCGGGCACCG TGATTTACGA
	AAATCCGCTG

9351	TTCCAGCTGA TCCAGTACAC GCCGACCACG CCGACGGTCA
	GCCAGCACCC

9401	GCTGTTGATG GTGCCGCCGT GCATCAACAA GTTCTACATC
	CTCGACCTGC

9451	AACCGGAAAA TTCGCTGGTG CGCTACGCGG TGGAGCAGGG
	CAACACCGTG

9501	TTCCTGATCT CGTGGAGCAA TCCGGACAAG TCGCTGGCCG
	GCACCACCTG

9551	GGACGACTAC GTGGAGCAGG GCGTGATCGA AGCGATCCGC
	ATCGTCCAGG

9601	ACGTCAGCGG CCAGGACAAG CTGAACATGT TCGGCTTCTG
	CGTGGGCGGC

9651	ACCATCGTTG CCACCGCACT GGCGGTACTG GCGGCGCGTG
	GCCAGCACCC

9701	GGCGGCCAGC CTGACCCTGC TGACCACCTT CCTCGACTTC
	AGCGACACCG

9751	GCGTGCTCGA CGTCTTCGTC GATGAAACCC AGGTCGCGCT
	GCGTGAACAG

9801	CAATTGCGCG ATGGCGGCCT GATGCCGGGC CGTGACCTGG
	CCTCGACCTT

9851	CTCGAGCCTG CGTCCGAACG ACCTGGTATG GAACTATGTG
	CAGTCGAACT

9901	ACCTCAAAGG CAATGAGCCG GCGGCGTTTG ACCTGCTGTT
	CTGGAATTCG

9951	GACAGCACCA ATTTGCCGGG CCCGATGTTC TGCTGGTACC
	TGCGCAACAC

10001	CTACCTGGAA AACAGCCTGA AAGTGCCGGG CAAGCTGACG
	GTGGCCGGCG

10051	AAAAGATCGA CCTCGGCCTG ATCGACGCCC CGGCCTTCAT
	CTACGGTTCG

10101	CGCGAAGACC ACATCGTGCC GTGGATGTCG GCGTACGGTT
	CGCTCGACAT

10151	CCTCAACCAG GGCAAGCCGG GCGCCAACCG CTTCGTGCTG
	GGCGCGTCCG

10201	GCCATATCGC CGGCGTGATC AACTCGGTGG CCAAGAACAA
	GCGCAGCTAC

10251	TGGATCAACG ACGGTGGCGC CGCCGATGCC CAGGCCTGGT
	TCGATGGCGC

10301	GCAGGAAGTG CCGGGCAGCT GGTGGCCGCA ATGGGCCGGG
	TTCCTGACCC

10351	AGCATGGCGG CAAGAAGGTC AAGCCCAAGG CCAAGCCCGG
	CAACGCCCGC

10401	TACACCGCGA TCGAGGCGGC GCCCGGCCGT TACGTCAAAG
	CCAAGGGCTG

10451	AGCGGCCGCT GAGTAATTCT GATATTAGAG GGAGCATTAA
	TGTGTTGTTG

10501	TGATGTGGTT TATATGGGGA AATTAAATAA ATGATGTATG
	TACCTCTTGC

10551	CTATGTAGGT TTGTGTGTTT TGTTTTGTTG TCTAGCTTTG
	GTTATTAAGT

10601	AGTAGGGACG TTCGTTCGTG TCTCAAAAAA AGGGGTACTA
	CCACTCTGTA

10651	GTGTATATGG ATGCTGGAAA TCAATGTGTT TTGTATTTGT
	TCACCTCCAT

10701	TGTTGAATTC AATGTCAAAT GTGTTTTGCG TTGTATTTGT
	GTAAAATTAC

10751	TATCTTTCTC GTCCGATGAT CAAAGTTTTA AGCAACAAAA
	CCAAGGGTGA

10801	AATTTAAACT GTGCTTTGTT GAAGATTCTT TTATCATATT
	GAAAATCAAA

10851	TTACTAGCAG CAGATTTTAC CTAGCATGAA ATTTTATCAA
	CAGTACAGCA

10901	CTCACTAACC AAGTTCCAAA CTAAGATGCG CCATTAACAT
	CAGCCAATAG

10951	GCATTTTCAG CAAGGCGCGC CCGCGCCGAT GTATGTGACA
	ACCCTCGGGA

11001	TTGTTGATTT ATTTCAAAAC TAAGAGTTTT TGTCTTATTG
	TTCTCGTCTA

11051	TTTTGGATAT CAATCTTAGT TTTATATCTT TTCTAGTTCT
	CTACGTGTTA

11101	AATGTTCAAC ACACTAGCAA TTTGGCCTGC CAGCGTATGG
	ATTATGGAAC

11151	TATCAAGTCT GTGACGCGCC GTACGTAGTG TTTATCTTTG
	TTGCTTTTCT

11201	GAACAATTTA TTTACTATGT AAATATATTA TCAATGTTTA
	ATCTATTTTA

11251	ATTTGCACAT GAATTTTCAT TTTATTTTTA CTTTACAAAA
	CAAATAAATA

11301	TATATGCAAA AAAATTTACA AACGATGCAC GGGTTACAAA
	CTAATTTCAT

11351	TAAATGCTAA TGCAGATTTT GTGAAGTAAA ACTCCAATTA
	TGATGAAAAA

11401	TACCACCAAC ACCACCTGCG AAACTGTATC CCAACTGTCC
	TTAATAAAAA

11451	TGTTAAAAAG TATATTATTC TCATTTGTCT GTCATAATTT
	ATGTACCCCA

11501	CTTTAATTTT TCTGATGTAC TAAACCGAGG GCAAACTGAA
	ACCTGTTCCT

11551	CATGCAAAGC CCCTACTCAC CATGTATCAT GTACGTGTCA
	TCACCCAACA

11601	ACTCCACTTT TGCTATATAA CAACACCCCC GTCACACTCT
	CCCTCTCTAA

11651	CACACACCCC ACTAACAATT CCTTCACTTG CAGCACTGTT
	GCATCATCAT

11701	CTTCATTGCA AAACCCTAAA CTTCACCTTC AACCGCGGCC
	GCATGGCTTC

11751	TATGATATCC TCTTCCGCTG TGACAACAGT CAGCCGTGCC
	TCTAGGGGGC

11801	AATCCGCCGC AGTGGCTCCA TTCGGCGGCC TCAAATCCAT
	GACTGGATTC

11851	CCAGTGAAGA AGGTCAACAC TGACATTACT TCCATTACAA
	GCAATGGTGG

11901	AAGAGTAAAG TGCATGCAGG TGTGGCCTCC AATTGGAAAG
	AAGAAGTTTG

11951	AGACTCTTTC CTATTTGCCA CCATTGACGA GAGATTCTAG
	AGTGACTCAG

12001	CGCATTGCGT ATGTGACCGG CGGCATGGGT GGTATCGGAA
	CCGCCATTTG

12051	CCAGCGGCTG GCCAAGGATG GCTTTCGTGT GGTGGCCGGT
	TGCGGCCCCA

12101	ACTCGCCGCG CCGCGAAAAG TGGCTGGAGC AGCAGAAGGC
	CCTGGGCTTC

12151	GATTTCATTG CCTCGGAAGG CAATGTGGCT GACTGGGACT
	CGACCAAGAC

12201	CGCATTCGAC AAGGTCAAGT CCGAGGTCGG CGAGGTTGAT
	GTGCTGATCA

12251	ACAACGCCGG TATCACCCGC GACGTGGTGT TCCGCAAGAT
	GACCCGCGCC

12301	GACTGGGATG CGGTGATCGA CACCAACCTG ACCTCGCTGT
	TCAACGTCAC

12351	CAAGCAGGTG ATCGACGGCA TGGCCGACCG TGGCTGGGGC
	CGCATCGTCA

12401	ACATCTCGTC GGTGAACGGG CAGAAGGGCC AGTTCGGCCA
	GACCAACTAC

12451	TCCACCGCCA AGGCCGGCCT GCATGGCTTC ACCATGGCAC
	TGGCGCAGGA

12501	AGTGGCGACC AAGGGCGTGA CCGTCAACAC GGTCTCTCCG
	GGCTATATCG

12551	CCACCGACAT GGTCAAGGCG ATCCGCCAGG ACGTGCTCGA
	CAAGATCGTC

12601	GCGACGATCC CGGTCAAGCG CCTGGGCCTG CCGGAAGAGA
	TCGCCTCGAT

12651	CTGCGCCTGG TTGTCGTCGG AGGAGTCCGG TTTCTCGACC
	GGCGCCGACT

12701	TCTCGCTCAA CGGCGGCCTG CATATGGGCT GAGCGGCCGC
	TGAGTAATTC

12751	TGATATTAGA GGGAGCATTA ATGTGTTGTT GTGATGTGGT
	TTATATGGGG

12801	AAATTAAATA AATGATGTAT GTACCTCTTG CCTATGTAGG
	TTTGTGTGTT

12851	TTGTTTTGTT GTCTAGCTTT GGTTATTAAG TAGTAGGGAC
	GTTCGTTCGT

12901	GTCTCAAAAA AAGGGGTACT ACCACTCTGT AGTGTATATG
	GATGCTGGAA

12951	ATCAATGTGT TTTGTATTTG TTCACCTCCA TTGTTGAATT
	CAATGTCAAA

13001	TGTGTTTTGC GTTGGTTATG TGTAAAATTA CTATCTTTCT
	CGTCCGATGA

13051	TCAAAGTTTT AAGCAACAAA ACCAAGGGTG AAATTTAAAC
	TGTGCTTTGT

13101	TGAAGATTCT TTTATCATAT TGAAAATCAA ATTACTAGCA
	GCAGATTTTA

13151	CCTAGCATGA AATTTTATCA ACAGTACAGC ACTCACTAAC
	CAAGTTCCAA

13201	ACTAAGATGC GCCATTAACA TCACCCAACA GGCATTTTCA
	GCAAGGCGCG

13251	TAAGGGGATC CGTACGTAAG TACGTACTCA AAATGCCAAC
	AAATAAAAAA

13301	AAAGTTGCTT TAATAATGCC AAAACAAATT AATAAAACAC
	TTACAACACC

13351	GGATTTTTTT TAATTAAAAT GTGCCATTTA GGATAAATAG
	TTAATATTTT

13401	TAATAATTAT TTAAAAAGCC GTATCTACTA AAATGATTTT
	TATTTGGTTG

13451	AAAATATTAA TATGTTTAAA TCAACACAAT CTATCAAAAT
	TAAACTAAAA

13501	AAAAAATAAG TGTACGTGGT TAACATTAGT ACAGTAATAT
	AAGCAACAAA

13551	TGAGAAATTA AGAAATTGAA AGCGAGTCTA ATTTTTAAAT
	TATGAACCTG

13601	CATATATAAA AGAAAAGAAA GAATCCAGGA AGAAAAGAAA
	TGAAACCATG

13651	CATGGTCCCC TCGTCATCAC GAGTTTCTGC CATTTGCAAT
	AGAAACACTG

13701	AAACACCTTT CTCTTTGTCA CTTAATTGAG ATGCCGAAGC
	CACCTCACAC

13751	CATGAACTTC ATGAGGTGTA GCACCCAAGG CTTCCATAGC
	CATGCATACT

13801	GAAGAATGTC TCAAGCTCAG CACCCTACTT CTGTGACGTG
	TCCCTCATTC

13851	ACCTTCCTCT CTTCCCTATA AATAACCACG CCTCAGGTTC
	TCCGCTTCAC

13901	AACTCAAACA TTCTCTCCAT TGGTCCTTAA ACACTCATCA
	GTCATCACCG

13951	CGGCCGCGGA ATTCATGGCT TCTATGATAT CCTCTTCCGC
	TGTGACAACA

14001	GTCAGCCGTG CCTCTAGGGG GCAATCCGCC GCAGTGGCTC
	CATTCGGCGG

14051	CCTCAAATCC ATGACTGGAT TCCCAGTGAA GAAGGTCAAC
	ACTGACATTA

14101	CTTCCATTAC AAGCAATGGT GGAAGAGTAA AGTGCATGCA
	GGTGTGGCCT

14151	CCAATTGGAA AGAAGAAGTT TGAGACTCTT TCCTATTTGC
	CACCATTGAC

14201	GAGAGATTCT AGAGTGACTG ACGTTGTCAT CGTATCCGCC
	GCCCGCACCG

14251	CGGTCGGCAA GTTTGGCGGC TCGCTGGCCA AGATCCCGGC
	ACCGGAACTG

14301	GGTGCCGTGG TCATCAAGGC CGCGCTGGAG CGCGCCGGCG
	TCAAGCCGGA

14351	GCAGGTGAGC GAAGTCATCA TGGGCCAGGT GCTGACCGCC
	GGTTCGGGCC

14401	AGAACCCCGC ACGCCAGGCC GCGATCAAGG CCGGCCTGCC
	GGCGATGGTG

14451	CCGGCCATGA CCATCAACAA GGTGTGCGGC TCGGGCCTGA
	AGGCCGTGAT

14501	GCTGGCCGCC AACGCGATCA TGGCGGGCGA CGCCGAGATC
	GTGGTGGCCG

14551	GCGGCCAGGA AAACATGAGC GCCGCCCCGC ACGTGCTGCC
	GGGCTCGCGC

14601	GATGGTTTCC GCATGGGCGA TGCCAAGCTG GTCGACACCA
	TGATCGTCGA

14651	CGGCCTGTGG GACGTGTACA ACCAGTACCA CATGGGCATC
	ACCGCCGAGA

14701	ACGTGGCCAA GGAATACGGC ATCACACGCG AGGCGCAGGA
	TGAGTTCGCC

14751	GTCGGCTCGC AGAACAAGGC CGAAGCCGCG CAGAAGGCCG
	GCAAGTTTGA

14801	CGAAGAGATC GTCCCGGTGC TGATCCCGCA GCGCAAGGGC
	GACCCGGTGG

14851	CCTTCAAGAC CGACGAGTTC GTGCGCCAGG GCGCCACGCT
	GGACAGCATG

14901	TCCGGCCTCA AGCCCGCCTT CGACAAGGCC GGCACGGTGA
	CCGCGGCCAA

14951	CGCCTCGGGC CTGAACGACG GCGCCGCCGC GGTGGTGGTG
	ATGTCGGCGG

15001	CCAAGGCCAA GGAACTGGGC CTGACCCCGC TGGCCACGAT
	CAAGAGCTAT

15051	GCCAACGCCG GTGTCGATCC CAAGGTGATG GGCATGGGCC
	CGGTGCCGGC

15101	CTCCAAGCGC GCCCTGTCGC GCGCCGAGTG GACCCCGCAA
	GACCTGGACC

15151	TGATGGAGAT CAACGAGGCC TTTGCCGCGC AGGCGCTGGC
	GGTGCACCAG

15201	CAGATGGGCT GGGACACCTC CAAGGTCAAT GTGAACGGCG
	GCGCCATCGC

15251	CATCGGCCAC CCGATCGGCG CGTCGGGCTG CCGTATCCTG
	GTGACGCTGC

15301	TGCACGAGAT GAAGCGCCGT GACGCGAAGA AGGGCCTGGC
	CTCGCTGTGC

15351	ATCGGCGGCG GCATGGGCGT GGCGCTGGCA GTCGAGCGCA
	AATAACTCGA

15401	GGCGGCCGCA GCCCTTTTTG TATGTGCTAC CCCACTTTTG
	TCTTTTTGGC

15451	AATAGTGCTA GCAACCAATA AATAATAATA ATAATAATGA
	ATAAGAAAAC

15501	AAAGGCTTTA GCTTGCCTTT TGTTCACTGT AAAATAATAA
	TGTAAGTACT

15551	CTCTATAATG AGTCACGAAA CTTTTGCGGG AATAAAAGGA
	GAAATTCCAA

15601	TGAGTTTTCT GTCAAATCTT CTTTTGTCTC TCTCTCTCTC
	TCTTTTTTTT

15651	TTTTCTTTCT TCTGAGCTTC TTGCAAAACA AAAGGCAAAC
	AATAACGATT

15701	GGTCCAATGA TAGTTAGCTT GATCGATGAT ATCTTTAGGA
	AGTGTTGGCA

15751	GGACAGGACA TGATGTAGAA GACTAAAATT GAAAGTATTG
	CAGACCCAAT

15801	AGTTGAAGAT TAACTTTAAG AATGAAGACG TCTTATCAGG
	TTCTTCATGA

15851	CTTAAGCTTT AAGAGGAGTC CACCATGGTA GATCTGACTA
	GTAACGGCCG

15901	CCAGTGTGCT GGAATTCTGC AGATGTGGAG CACGACACTC
	TCGTCTACTC

15951	CAAGAATATC AAAGATACAG TCTCAGAAGA CCAAAGGGCT
	ATTGAGACTT

16001	TTCAACAAAG GGTAATATCG GGAAACCTCC TCGGATTCCA
	TTGCCCAGCT

16051	ATCTGTCACT TCATCAAAAG GACAGTAGAA AAGGAAGGTG
	GCACCTACAA

16101	ATGCCATCAT TGCGATAAAG GAAAGGCTAT CGTTCAAGAT
	GCCTCTGCCG

16151	ACAGTGGTCC CAAAGAATCA CCCCCACCCA CGAGGAGCAT
	CGTGGAAAAA

16201	GAAGACGTTC CAACCACGTC TTCAAAGCAA GTGGATTGAT
	GTGATAACAT

16251	GGTGGAGCAC GACACTCTCG TCTACTCCAA GAATATCAAA
	GATACAGTCT

16301	CAGAAGACCA AAGGGCTATT GAGACTTTTC AACAAAGGGT
	AATATCGGGA

16351	AACCTCCTCG GATTCCATTG CCCAGCTATC TGTCACTTCA
	TCAAAAGGAC

16401	AGTAGAAAAG GAAGGTGGCA CCTACAAATG CCATCATTGC
	GATAAAGGAA

16451	AGGCTATCGT TCAAGATGCC TCTGCCGACA GTGGTCCCAA
	AGATGGACCC

16501	CCACCCACGA GGAGCATCGT GGAAAAAGAA GACGTTCCAA
	CCACGTCTTC

16551	AAAGCAAGTG GATTGATGTG ATATCTCCAC TGACGTAAGG
	GATGACGCAC

16601	AATCCCACTA TCCTTCGCAA GACCTTCCTC TATATAAGGA
	AGTTCATTTC

16651	ATTTGGAGAG GACACGCTGA AATCACCAGT CTCTCTCTAC
	AAATCTATCT

16701	CTCTCGAGCT TTCGCAGATC TGTCGATCGA CCATGGACTC
	CAAAGAATCA

16751	TTAACTCCTG GTAGAGAAGA AAACCCCAGC AGTGTGCTTG
	CTCAGGAGAG

16801	GGGAGATGTG ATGGACTTCT ATAAAACCCT AAGAGGAGGA
	GCTACTGTGA

16851	AGGTTTCTGC GTCTTCACCC TCACTGGCTG TCGCTTCTCA
	ATCAGACTCC

16901	AAGCAGCGAA GACTTTTGGT TGATTTTCCA AAAGGCTCAG
	TAAGCAATGC

16951	GCAGCAGCCA GATCTGTCCA AAGCAGTTTC ACTCTCAATG
	GGACTGTATA

17001	TGGGAGAGAC AGAAACAAAA GTGATGGGAA ATGACCTGGG
	ATTCCCACAG

17051	CAGGGCCAAA TCAGCCTTTC CTCGGGGGAA ACAGACTTAA
	AGCTTTTGGA

17101	AGAAAGCATT GCAAACCTCA ATAGGTCGAC CAGTGTTCCA
	GAGAACCCCA

17151	AGAGTTCAGC ATCCACTGCT GTGTCTGCTG CCCCCACAGC
	TAGTTCTGCG

17201	GCCCCCCCGA CCGATGTCAG CCTGGGGGAC GAGCTCCACT
	TAGACGGCGA

17251	GGACGTGGCG ATGGCGCATG CCGACGCGCT AGACGATTTC
	GATCTGGACA

17301	TGTTGGGGGA CGGGGATTCC CCGGGTCCGG GATTTACCCC
	CCACGACTCC

17351	GCCCCCTACG GCGCTCTGGA TATGGCCGAC TTCGAGTTTG
	AGCAGATGTT

17401	TACCGATGCC CTTGGAATTG ACGAGTACGG TGGGACTAGC
	TCCAGCTCCT

17451	CAACAGCAAC AACAGGACCA CCTCCCAAAC TCTGCCTGGT
	GTGCTCTGAT

17501	GAAGCTTCAG GATGTCATTA TGGAGTCTTA ACTTGTGGAA
	GCTGTAAAGT

17551	TTTCTTCAAA AGAGCAGTGG AAGGACAGCA CAATTACCTA
	TGTGCTGGAA

17601	GGAATGATTG CATCATCGAT AAAATTCGAA GAAAAAACTG
	CCCAGCATGC

17651	CGCTATCGAA AATGTCTTCA GGCTGGAATG AACCTGGAAG
	CTCGAAAAAC

17701	AAAGAAAAAA ATAAAAGGAA TTGCTCGACA AAGGCCCGAG
	TGCGTGGTGC

17751	CGGAGAACCA GTGTGCAATG AAACGGAAAG AGAAAAAGGC
	GCAGAGGGAA

17801	AAAGACAAAT TGCCCGTCAG TACGACGACA GTAGACGATC
	ACATGCCTCC

17851	CATCATGCAA TGTGACCCTC CGCCCCCAGA GGCCGCTAGA
	ATTCTGGAAT

17901	GTTTGCAGCA CGAGGTGGTG CCACGATTCC TGAATGAGAA
	GCTAATGGAA

17951	CAGAACAGAT TGAAGAACGT GCCCCCCCTC ACTGCCAATC
	AGAAGTCGTT

18001	GATCGCAAGG CTCGTGTGGT ACCAGGAAGG CTATGAACAA
	CCTTCCGAGG

18051	AAGACCTGAA GAGGGTTACA CAGTCGGACG AGGACGACGA
	AGACTCGGAT

18101	ATGCCGTTCC GTCAGATTAC CGAGATGACG ATTCTCACAG
	TGCAGCTCAT

18151	CGTAGAATTC GCTAAGGGCC TCCCGGGCTT CGCCAAGATC
	TCGCAGTCGG

18201	ACCAGATCAC GTTATTAAAG GCGTGCTCAA GTGAGGTGAT
	GATGCTCCGA

18251	GTGGCTCGGC GGTATGACGC GGCCACCGAC AGCGTACTGT
	TCGCGAACAA

18301	CCAGGCGTAC ACTCGCGACA ACTACCGCAA GGCAGGCATG
	GCGTACGTCA

18351	TCGAGGACCT GCTGCACTTC TGTCGGTGCA TGTACTCCAT
	GATGATGGAT

18401	AACGTGCATT ATGCGCTGCT TACAGCCATT GTCATCTTCT
	CAGACCGGCC

18451	CGGGCTTGAG CAACCCCTGT TGGTGGAGGA GATCCAGAGA
	TATTACCTGA

18501	ACACGCTACG GGTGTACATC CTGAACCAGA ACAGCGCGTC
	GCCCCGCTGC

18551	GCCGTCATCT TCGGCAAGAT CCTGGGCATA CTGACGGAGA
	TCCGCACGCT

18601	GGGCATGCAG AACTCCAACA TGTGCATCTC CCTCAAGCTG
	AAGAACAGGA

18651	AGCTGCCGCC GTTCCTCGAG GAGATCTGGG ACGTGGCGGA
	CGTGGCGACG

18701	ACGGCGACGC CGGTGGCGGC GGAGGCGCCG GCGCTCTAGC
	CCCCGCGCCG

18751	CCCGCCCGGC CGCGCGCACG TCTAGCGCGC CTCAGGAGAG
	AACGCTCATA

18801	GACTGGCTAG TTTTAGTGAA GTGCACGGAC ACTGACGTCG
	GACGTGATCA

18851	ACCTATTTAT AAGGACTGCG AATTTTACCA CTTAAGAGGG
	CACACCCGTA

18901	CCCGATTTCG TACGGGAATT CCTGCAGCCC GGGGGATCCT
	TAATTAACTC

18951	GAGGAATTCA TCGATTCCGC GGGTACCGAG CTCGATCCGT
	CGACCTGCAG

19001	ATCGTTCAAA CATTTGGCAA TAAAGTTTCT TAAGATTGAA
	TCCTGTTGCC

19051	GGTCTTGCGA TGATTATCAT ATAATTTCTG TTGAATTACG
	TTAAGCATGT

19101	AATAATTAAC ATGTAATGCA TGACGTTATT TATGAGATGG
	GTTTTTATGA

19151	TTAGAGTCCC GCAATTATAC ATTTAATACG CGATAGAAAA
	CAAAATATAG

19201	CGCGCAAACT AGGATAAATT ATCGCGCGCG GTGTCATCTA
	TGTTACTAGA

19251	TCTGGCGCGC CCCTAGGTCT AGAGTCGACT GTTTAAACGG
	TCCGTGACCA

19301	TGATTACGCC AAGCTTCGAC TGTACAGGAT GTTCTAGCTA
	CTCGAGTAGC

19351	TAGAACATCC TGTACAGTCG AGTAGCTAGA ACATCCTGTA
	CAGTCGACTA

19401	GCTAGAACAT CCTGTACAGT CGAGTAGCTA GAACATCCTG
	TACAGTCGAG

19451	TAGCTAGACA TCCTGTACAG GATCCCTATA TAAGGAAGTT
	CATTTCATTT

19501	GGAGAGAACA CGGGGGATCG GGTATCGTTA ATTAAGTTTA
	TCAACAAGTT

19551	TGTACAAAAA AGCAGGCTCC GCGGCCGCCC CCTTCACCTT
	CCTCGACTTC

19601	AGCGACACCG GCGTGCTCGA CGTCTTCGTC GATGAAACCC
	AGGTCGCGCT

19651	GCGTGAACAG CAATTGCGCG ATGGCGGCCT GATGCCGGGC
	CGTGACCTGG

19701	CCTCGACCTT CTCGAGCCTG CGTCCGAACG ACCTGGTATG
	GAACTATGTG

19751	CAGTCGAACT ACCTCAAAGG CAATGAGCCG GCGGCGTTTG
	ACCTGCTGTT

19801	CTGGAATTCG GACAGCACCA ATTTGCCGGG CCCGATGTTC
	TGCTGGTACC

19851	TGCGCAACAC CTACCTGGAA AACAGCCTGA AAGTGCCGGG
	CAAGCTGACG

19901	GTGGCCGGCG AAAAGATCGA CCTCGGCCTG ATCGACGCCC
	CGGCCTTCAT

19951	CTACGGTTCG CGCGAAGACC ACATCGTGCC GTGGATGTCG
	GCGTACGGTT

20001	CGCTCGACAT CCTCAACCAG GGCAAGCCGG GCGCCAACCG
	CTTCGTGCTG

20051	GGCGCGTCCG GCCATATCGC CGGCGTGATC AACTCGGTGG
	CCAAGAACAA

20101	GCGCAGCTAC TGGATCAACG ACGGTGGCGC CGCCGATGCC
	CAGGCCTGGT

20151	TCGATGGCGC GCAGGAAGTG CCGGGCAGCT GGTGGCCGCA
	ATGGGCCGGG

20201	TTCCTGACCC AGCATGGCGG CAAGAAGGTC AAGCCCAAGG
	CCAAAAGGGT

20251	GGGCGCGCCG ACCCAGCTTT CTTGTACAAA GTGGTTGATC
	CTGCAGGGTC

20301	CGTCGCTTCT CTTCCATTTC TTCTCATTTT CGATTTTGAT
	TCTTATTTCT

20351	TTCCAGTAGC TCCTGCTCTG TGAATTTCTC CGCTCACGAT
	AGATCTGCTT

20401	ATACTCCTTA CATTCAACCT TAGATCTGGT CTCGATTCTC
	TGTTTCTCTG

20451	TTTTTTTCTT TTGGTCGAGA ATCTGATGTT TGTTTATGTT
	CTGTCACCAT

20501	TAATAATAAT GAACTCTCTC ATTCATACAA TGATTAGTTT
	CTCTCGTCTA

20551	CAAAACGATA TGTTGCATTT TCACTTTTCT TCTTTTTTTC
	TAAGATGATT

20601	TGCTTTGACC AATTTGTTTA GATCTTTATT CTATTTTATT
	TTCTGGTGGG

20651	TTGGTGGAAA TTGAAAAAAA AATACAAGCA TAAATTGTTA
	TTTGTTAATG

20701	TATTCATTTT TTGGCTATTT GTTCTGGGTA AAAATCTGCT
	TCTACTATTG

20751	AATCTTTCCT GGATTTTTTA CTCCTATTGG GTTTTTATAG
	TAAAAATACA

20801	TAATAAAAGG AAAACAAAAG TTTTATAGAT TCTCTTAAAC
	CCCTTACGAT

20851	AAAAGTTGGA ATCAAAATAA TTCAGGATCA GATGCTCTTT
	GATTGATTCA

20901	GATGCGATTA CAGTTGCATG GCAAATTTTC TAGATCCGTC
	GTCACATTTT

20951	ATTTTCTGTT TAAATATCTA AATCTGATAT ATGATGTCGA
	CAAATTCTGG

21001	TGGCTTATAC ATCACTTCAA CTGTTTTCTT TTGGCTTTGT
	TTGTCAACTT

21051	GGTTTTCAAT ACGATTTGTG ATTTCGATCG CTGAATTTTT
	AATACAAGCA

21101	AACTGATGTT AACCACAAGC AAGAGATGTG ACCTGCCTTA
	TTAACATCGT

21151	ATTACTTACT ACTAGTCGTA TTCTCAACGC AATCGTTTTT
	GTATTTCTCA

21201	CATTATGCCG CTTCTCTACT CTTTATTCCT TTTGGTCCAC
	GCATTTTCTA

21251	TTTGTGGCAA TCCCTTTCAC AACCTGATTT CCCACTTTGG
	ATCATTTGTC

21301	TGAAGACTCT CTTGAATCGT TACCACTTGT TTCTTGTGCA
	TGCTCTGTTT

21351	TTTAGAATTA ATGATAAAAC TATTCCATAG TCTTGAGTTT
	TCAGCTTGTT

21401	GATTCTTTTG CTTTTGGTTT TCTGCAGGTT TAAACATCAA
	CCACTTTGTA

21451	CAAGAAAGCT GGGTCGGCGC GCCCACCCTT TTGGCCTTGG
	GCTTGACCTT

21501	CTTGCCGCCA TGCTGGGTCA GGAACCCGGC CCATTGCGGC
	CACCAGCTGC

21551	CCGGCACTTC CTGCGCGCCA TCGAACCAGG CCTGGGCATC
	GGCGGCGCCA

21601	CCGTCGTTGA TCCAGTAGCT GCGCTTGTTC TTGGCCACCG
	AGTTGATCAC

21651	GCCGGCGATA TGGCCGGACG CGCCCAGCAC GAAGCGGTTG
	GCGCCCGGCT

21701	TGCCCTGGTT GAGGATGTCG AGCGAACCGT ACGCCGACAT
	CCACGGCACG

21751	ATGTGGTCTT CGCGCGAACC GTAGATGAAG GCCGGGGCGT
	CGATCAGGCC

21801	GAGGTCGATC TTTTCGCCGG CCACCGTCAG CTTGCCCGGC
	ACTTTCAGGC

21851	TGTTTTCCAG GTAGGTGTTG CGCAGGTACC AGCAGAACAT
	CGGGCCCGGC

21901	AAATTGGTGC TGTCCGAATT CCAGAACAGC AGGTCAAACG
	CCGCCGGCTC

21951	ATTGCCTTTG AGGTAGTTCG ACTGCACATA GTTCCATACC
	AGGTCGTTCG

22001	GACGCAGGCT CGAGAAGGTC GAGGCCAGGT CACGGCCCGG
	CATCAGGCCG

22051	CCATCGCGCA ATTGCTGTTC ACGCAGCGCG ACCTGGGTTT
	CATCGACGAA

22101	GACGTCGAGC ACGCCGGTGT CGCTGAAGTC GAGGAAGGTG
	AAGGGGGCGG

22151	CCGCGGAGCC TGCTTTTTTG TACAAACTTG TTGATCTCGA
	GCGGCGCGCC

22201	GTTCGAGTAT TATGGCATTG GGAAAACTGT TTTTCTTGTA
	CCATTTGTTG

22251	TGCTTGTAAT TTACTGTGTT TTTTATTCGG TTTTCGCTAT
	CGAACTGTGA

22301	AATGGAAATG GATGGAGAAG AGTTAATGAA TGATATGGTC
	CTTTTGTTCA

22351	TTCTCAAATT AATATTATTT GTTTTTTCTC TTATTTGTTG
	TGTGTTGAAT

22401	TTGAAATTAT AAGAGATATG CAAACATTTT GTTTTGAGTA
	AAAATGTGTC

22451	AAATCGTGGC CTCTAATGAC CGAAGTTAAT ATGAGGAGTA
	AAACACTGTT

22501	TAAACCCTGC AGGATTT

Vector: pPhaA-RNAi/glyP

(SEQ ID NO: 5)

1	AAATAGAAGG TAATTATCCA AGATGTAGCA TCAAGAATCC
	AATGTTTACG

51	GGAAAAACTA TGGAAGTATT ATGTGAGCTC AGCAAGAAGC
	AGATCAATAT

101	GCGGCACATA TGCAACCTAT GTTCAAAAAT GAAGAATGTA
	CAGATACAAG

151	ATCCTATACT GCCAGAATAC GAAGAAGAAT ACGTAGAAAT
	TGAAAAAGAA

201	GAACCAGGCG AAGAAAAGAA TCTTGAAGAC GTAAGCACTG
	ACGACAACAA

251	TGAAAAGAAG AAGATAAGGT CGGTGATTGT GAAAGAGACA
	TAGAGGACAC

301	ATGTAAGGTG GAAAATGTAA GGGCGGAAAG TAACCTTATC
	ACAAAGGAAT

351	CTTATCCCCC ACTACTTATC CTTTTATATT TTTCCGTGTC
	ATTTTTGCCC

401	TTGAGTTTTC CTATATAAGG AACCAAGTTC GGCATTTGTG
	AAAACAAGAA

451	AAAATTGGTG TAAGCTATTT TCTTTGAAGT ACTGAGGATA
	CAACTTCAGA

501	GAAATTTGTA AGAAAGTGGA TCGAAACCAT GGCCTCCTCC
	GAGAACGTCA

551	TCACCGAGTT CATGCGCTTC AAGGTGCGCA TGGAGGGCAC
	CGTGAACGGC

601	CACGAGTTCG AGATCGAGGG CGAGGGCGAG GGCCGCCCCT
	ACGAGGGCCA

651	CAACACCGTG AAGCTGAAGG TGACCAAGGG CGGCCCCCTG
	CCCTTCGCCT

701	GGGACATCCT GTCCCCCCAG TTCCAGTACG GCTCCAAGGT
	GTACGTGAAG

751	CACCCCGCCG ACATCCCCGA CTACAAGAAG CTGTCCTTCC
	CCGAGGGCTT

801	CAAGTGGGAG CGCGTGATGA ACTTCGAGGA CGGCGGCGTG
	GCGACCGTGA

851	CCCAGGACTC CTCCCTGCAG GACGGCTGCT TCATCTACAA
	GGTGAAGTTC

901	ATCGGCGTGA ACTTCCCCTC CGACGGCCCC GTGATGCAGA
	AGAAGACCAT

951	GGGCTGGGAG GCCTCCACCG AGCGCCTGTA CCCCCGCGAC
	GGCGTGCTGA

1001	AGGGCGAGAC CCACAAGGCC CTGAAGCTGA AGGACGGCGG
	CCACTACCTG

1051	GTGGAGTTCA AGTCCATCTA CATGGCCAAG AAGCCCGTGC
	AGCTGCCCGG

1101	CTACTACTAC GTGGACGCCA AGCTGGACAT CACCTCCCAC
	AACGAGGACT

1151	ACACCATCGT GGAGCAGTAC GAGCGCACCG AGGGCCGCCA
	CCACCTGTTC

1201	CTGGTACCAA TGAGCTCTGT CCAACAGTCT CAGGGTTAAT
	GTCTATGTAT

1251	CTTAAATAAT GTTGTCGGCG ATCGTTCAAA CATTTGGCAA
	TAAAGTTTCT

1301	TAAGATTGAA TCCTGTTGCC GGTCTTGCGA TGATTATCAT
	ATAATTTCTG

1351	TTGAATTACG TTAAGCATGT AATAATTAAC ATGTAATGCA
	TGACGTTATT

1401	TATGAGATGG GTTTTTATGA TTAGAGTCCC GCAATTATAC
	ATTTAATACG

1451	CGATAGAAAA CAAAATATAG CGCGCAAACT AGGATAAATT
	ATCGCGCGCG

1501	GTGTCATCTA TGTTACTAGA TCGGGAATTA AACTATCAGT
	GTTTGACAGG

1551	ATATATTGGC GGGTAAACCT AAGAGAAAAG AGCGTTTATT
	AGAATAACGG

1601	ATATTTAAAA GGGCGTGAAA AGGTTTATCC GTTCGTCCAT
	TTGTATGTGC

1651	ATGCCAACCA CAGGGTTCCC CTCGGGATCA AAGTACTTTG
	ATCCAACCCC

1701	TCCGCTGCTA TAGTGCAGTC GGCTTCTGAC GTTCAGTGCA
	GCCGTCTTCT

1751	GAAAACGACA TGTCGCACAA GTCCTAAGTT ACGCGACAGG
	CTGCCGCCCT

1801	GCCCTTTTCC TGGCGTTTTC TTGTCGCGTG TTTTAGTCGC
	ATAAAGTAGA

1851	ATACTTGCGA CTAGAACCGG AGACATTACG CCATGAACAA
	GAGCGCCGCC

1901	GCTGGCCTGC TGGGCTATGC CCGCGTCAGC ACCGACGACC
	AGGACTTGAC

1951	CAACCAACGG GCCGAACTGC ACGCGGCCGG CTGCACCAAG
	CTGTTTTCCG

2001	AGAAGATCAC CGGCACCAGG CGCGACCGCC CGGAGCTGGC
	CAGGATGCTT

2051	GACCACCTAC GCCCTGGCGA CGTTGTGACA GTGACCAGGC
	TAGACCGCCT

2101	GGCCCGCAGC ACCCGCGACC TACTGGACAT TGCCGAGCGC
	ATCCAGGAGG

2151	CCGGCGCGGG CCTGCGTAGC CTGGCAGAGC CGTGGGCCGA
	CACCACCACG

2201	CCGGCCGGCC GCATGGTGTT GACCGTGTTC GCCGGCATTG
	CCGAGTTCGA

2251	GCGTTCCCTA ATCATCGACC GCACCCGGAG CGGGCGCGAG
	GCCGCCAAGG

2301	CCCGAGGCGT GAAGTTTGGC CCCCGCCCTA CCCTCACCCC
	GGCACAGATC

2351	GCGCACGCCC GCGAGCTGAT CGACCAGGAA GGCCGCACCG
	TGAAAGAGGC

2401	GGCTGCACTG CTTGGCGTGC ATCGCTCGAC CCTGTACCGC
	GCACTTGAGC

2451	GCAGCGAGGA AGTGACGCCC ACCGAGGCCA GGCGGCGCGG
	TGCCTTCCGT

2501	GAGGACGCAT TGACCGAGGC CGACGCCCTG GCGGCCGCCG
	AGAATGAACG

2551	CCAAGAGGAA CAAGCATGAA ACCGCACCAG GACGGCCAGG
	ACGAACCGTT

2601	TTTCATTACC GAAGAGATCG AGGCGGAGAT GATCGCGGCC
	GGGTACGTGT

2651	TCGAGCCGCC CGCGCACGTC TCAACCGTGC GGCTGCATGA
	AATCCTGGCC

2701	GGTTTGTCTG ATGCCAAGCT GGCGGCCTGG CCGGCCAGCT
	TGGCCGCTGA

2751	AGAAACCGAG CGCCGCCGTC TAAAAAGGTG ATGTGTATTT
	GAGTAAAACA

2801	GCTTGCGTCA TGCGGTCGCT GCGTATATGA TGCGATGAGT
	AAATAAACAA

2851	ATACGCAAGG GGAACGCATG AAGGTTATCG CTGTACTTAA
	CCAGAAAGGC

2901	GGGTCAGGCA AGACGACCAT CGCAACCCAT CTAGCCCGCG
	CCCTGCAACT

2951	CGCCGGGGCC GATGTTCTGT TAGTCGATTC CGATCCCCAG
	GGCAGTGCCC

3001	GCGATTGGGC GGCCGTGCGG GAAGATCAAC CGCTAACCGT
	TGTCGGCATC

3051	GACCGCCCGA CGATTGACCG CGACGTGAAG GCCATCGGCC
	GGCGCGACTT

3101	CGTAGTGATC GACGGAGCGC CCCAGGCGGC GGACTTGGCT
	GTGTCCGCGA

3151	TCAAGGCAGC CGACTTCGTG CTGATTCCGG TGCAGCCAAG
	CCCTTACGAC

3201	ATATGGGCCA CCGCCGACCT GGTGGAGCTG GTTAAGCAGC
	GCATTGAGGT

3251	CACGGATGGA AGGCTACAAG CGGCCTTTGT CGTGTCGCGG
	GCGATCAAAG

3301	GCACGCGCAT CGGCGGTGAG GTTGCCGAGG CGCTGGCCGG
	GTACGAGCTG

3351	CCCATTCTTG AGTCCCGTAT CACGCAGCGC GTGAGCTACC
	CAGGCACTGC

3401	CGCCGCCGGC ACAACCGTTC TTGAATCAGA ACCCGAGGGC
	GACGCTGCCC

3451	GCGAGGTCCA GGCGCTGGCC GCTGAAATTA AATCAAAACT
	CATTTGAGTT

3501	AATGAGGTAA AGAGAAAATG AGCAAAAGCA CAAACACGCT
	AAGTGCCGGC

3551	CGTCCGAGCG CACGCAGCAG CAAGGCTGCA ACGTTGGCCA
	GCCTGGCAGA

3601	CACGCCAGCC ATGAAGCGGG TCAACTTTCA GTTGCCGGCG
	GAGGATCACA

3651	CCAAGCTGAA GATGTACGCG GTACGCCAAG GCAAGACCAT
	TACCGAGCTG

3701	CTATCTGAAT ACATCGCGCA GCTACCAGAG TAAATGAGCA
	AATGAATAAA

3751	TGAGTAGATG AATTTTAGCG GCTAAAGGAG GCGGCATGGA
	AAATCAAGAA

3801	CAACCAGGCA CCGACGCCGT GGAATGCCCC ATGTGTGGAG
	GAACGGGCGG

3851	TTGGCCAGGC GTAAGCGGCT GGGTTGTCTG CCGGCCCTGC
	AATGGCACTG

3901	GAACCCCCAA GCCCGAGGAA TCGGCGTGAC GGTCGCAAAC
	CATCCGGCCC

3951	GGTACAAATC GGCGCGGCGC TGGGTGATGA CCTGGTGGAG
	AAGTTGAAGG

4001	CCGCGCAGGC CGCCCAGCGG CAACGCATCG AGGCAGAAGC
	ACGCCCCGGT

4051	GAATCGTGGC AAGCGGCCGC TGATCGAATC CGCAAAGAAT
	CCCGGCAACC

4101	GCCGGCAGCC GGTGCGCCGT CGATTAGGAA GCCGCCCAAG
	GGCGACGAGC

4151	AACCAGATTT TTTCGTTCCG ATGCTCTATG ACGTGGGCAC
	CCGCGATAGT

4201	CGCAGCATCA TGGACGTGGC CGTTTTCCGT CTGTCGAAGC
	GTGACCGACG

4251	AGCTGGCGAG GTGATCCGCT ACGAGCTTCC AGACGGGCAC
	GTAGAGGTTT

4301	CCGCAGGGCC GGCCGGCATG GCCAGTGTGT GGGATTACGA
	CCTGGTACTG

4351	ATGGCGGTTT CCCATCTAAC CGAATCCATG AACCGATACC
	GGGAAGGGAA

4401	GGGAGACAAG CCCGGCCGCG TGTTCCGTCC ACACGTTGCG
	GACGTACTCA

4451	AGTTCTGCCG GCGAGCCGAT GGCGGAAAGC AGAAAGACGA
	CCTGGTAGAA

4501	ACCTGCATTC GGTTAAACAC CACGCACGTT GCCATGCAGC
	GTACGAAGAA

4551	GGCCAAGAAC GGCCGCCTGG TGACGGTATC CGAGGGTGAA
	GCCTTGATTA

4601	GCCGCTACAA GATCGTAAAG AGCGAAACCG GGCGGCCGGA
	GTACATCGAG

4651	ATCGAGCTAG CTGATTGGAT GTACCGCGAG ATCACAGAAG
	GCAAGAACCC

4701	GGACGTGCTG ACGGTTCACC CCGATTACTT TTTGATCGAT
	CCCGGCATCG

4751	GCCGTTTTCT CTACCGCCTG GCACGCCGCG CCGCAGGCAA
	GGCAGAAGCC

4801	AGATGGTTGT TCAAGACGAT CTACGAACGC AGTGGCAGCG
	CCGGAGAGTT

4851	CAAGAAGTTC TGTTTCACCG TGCGCAAGCT GATCGGGTCA
	AATGACCTGC

4901	CGGAGTACGA TTTGAAGGAG GAGGCGGGGC AGGCTGGCCC
	GATCCTAGTC

4951	ATGCGCTACC GCAACCTGAT CGAGGGCGAA GCATCCGCCG
	GTTCCTAATG

5001	TACGGAGCAG ATGCTAGGGC AAATTGCCCT AGCAGGGGAA
	AAAGGTCGAA

5051	AAGGTCTCTT TCCTGTGGAT AGCACGTACA TTGGGAACCC
	AAAGCCGTAC

5101	ATTGGGAACC GGAACCCGTA CATTGGGAAC CCAAAGCCGT
	ACATTGGGAA

5151	CCGGTCACAC ATGTAAGTGA CTGATATAAA AGAGAAAAAA
	GGCGATTTTT

5201	CCGCCTAAAA CTCTTTAAAA CTTATTAAAA CTCTTAAAAC
	CCGCCTGGCC

5251	TGTGCATAAC TGTCTGGCCA GCGCACAGCC GAAGAGCTGC
	AAAAAGCGCC

5301	TACCCTTCGG TCGCTGCGCT CCCTACGCCC CGCCGCTTCG
	CGTCGGCCTA

5351	TCGCGGCCGC TGGCCGCTCA AAAATGGCTG GCCTACGGCC
	AGGCAATCTA

5401	CCAGGGCGCG GACAAGCCGC GCCGTCGCCA CTCGACCGCC
	GGCGCCCACA

5451	TCAAGGCACC CTGCCTCGCG CGTTTCGGTG ATGACGGTGA
	AAACCTCTGA

5501	CACATGCAGC TCCCGGAGAC GGTCACAGCT TGTCTGTAAG
	CGGATGCCGG

5551	GAGCAGACAA GCCCGTCAGG GCGCGTCAGC GGGTGTTGGC
	GGGTGTCGGG

5601	GCGCAGCCAT GACCCAGTCA CGTAGCGATA GCGGAGTGTA
	TACTGGCTTA

5651	ACTATGCGGC ATCAGAGCAG ATTGTACTGA GAGTGCACCA
	TATGCGGTGT

5701	GAAATACCGC ACAGATGCGT AAGGAGAAAA TACCGCATCA
	GGCGCTCTTC

5751	CGCTTCCTCG CTCACTGACT CGCTGCGCTC GGTCGTTCGG
	CTGCGGCGAG

5801	CGGTATCAGC TCACTCAAAG GCGGTAATAC GGTTATCCAC
	AGAATCAGGG

5851	GATAACGCAG GAAAGAACAT GTGAGCAAAA GGCCAGCAAA
	AGGCCAGGAA

5901	CCGTAAAAAG GCCGCGTTGC TGGCGTTTTT CCATAGGCTC
	CGCCCCCCTG

5951	ACGAGCATCA CAAAAATCGA CGCTCAAGTC AGAGGTGGCG
	AAACCCGACA

6001	GGACTATAAA GATACCAGGC GTTTCCCCCT GGAAGCTCCC
	TCGTGCGCTC

6051	TCCTGTTCCG ACCCTGCCGC TTACCGGATA CCTGTCCGCC
	TTTCTCCCTT

6101	CGGGAAGCGT GGCGCTTTCT CATAGCTCAC GCTGTAGGTA
	TCTCAGTTCG

6151	GTGTAGGTCG TTCGCTCCAA GCTGGGCTGT GTGCACGAAC
	CCCCCGTTCA

6201	GCCCGACCGC TGCGCCTTAT CCGGTAACTA TCGTCTTGAG
	TCCAACCCGG

6251	TAAGACACGA CTTATCGCCA CTGGCAGCAG CCACTGGTAA
	CAGGATTAGC

6301	AGAGCGAGGT ATGTAGGCGG TGCTACAGAG TTCTTGAAGT
	GGTGGCCTAA

6351	CTACGGCTAC ACTAGAAGGA CAGTATTTGG TATCTGCGCT
	CTGCTGAAGC

6401	CAGTTACCTT CGGAAAAAGA GTTGGTAGCT CTTGATCCGG
	CAAACAAACC

6451	ACCGCTGGTA GCGGTGGTTT TTTTGTTTGC AAGCAGCAGA
	TTACGCGCAG

6501	AAAAAAAGGA TCTCAAGAAG ATCCTTTGAT CTTTTCTACG
	GGGTCTGACG

6551	CTCAGTGGAA CGAAAACTCA CGTTAAGGGA TTTTGGTCAT
	GCATTCTAGG

6601	TACTAAAACA ATTCATCCAG TAAAATATAA TATTTTATTT
	TCTCCCAATC

6651	AGGCTTGATC CCCAGTAAGT CAAAAAATAG CTCGACATAC
	TGTTCTTCCC

6701	CGATATCCTC CCTGATCGAC CGGACGCAGA AGGCAATGTC
	ATACCACTTG

6751	TCCGCCCTGC CGCTTCTCCC AAGATCAATA AAGCCACTTA
	CTTTGCCATC

6801	TTTCACAAAG ATGTTGCTGT CTCCCAGGTC GCCGTGGGAA
	AAGACAAGTT

6851	CCTCTTCGGG CTTTTCCGTC TTTAAAAAAT CATACAGCTC
	GCGCGGATCT

6901	TTAAATGGAG TGTCTTCTTC CCAGTTTTCG CAATCCACAT
	CGGCCAGATC

6951	GTTATTCAGT AAGTAATCCA ATTCGGCTAA GCGGCTGTCT
	AAGCTATTCG

7001	TATAGGGACA ATCCGATATG TCGATGGAGT GAAAGAGCCT
	GATGCACTCC

7051	GCATACAGCT CGATAATCTT TTCAGGGCTT TGTTCATCTT
	CATACTCTTC

7101	CGAGCAAAGG ACGCCATCGG CCTCACTCAT GAGCAGATTG
	CTCCAGCCAT

7151	CATGCCGTTC AAAGTGCAGG ACCTTTGGAA CAGGCAGCTT
	TCCTTCCAGC

7201	CATAGCATCA TGTCCTTTTC CCGTTCCACA TCATAGGTGG
	TCCCTTTATA

7251	CCGGCTGTCC GTCATTTTTA AATATAGGTT TTCATTTTCT
	CCCACCAGCT

7301	TATATACCTT AGCAGGAGAC ATTCCTTCCG TATCTTTTAC
	GCAGCGGTAT

7351	TTTTCGATCA GTTTTTTCAA TTCCGGTGAT ATTCTCATTT
	TAGCCATTTA

7401	TTATTTCCTT CCTCTTTTCT ACAGTATTTA AAGATACCCC
	AAGAAGCTAA

7451	TTATAACAAG ACGAACTCCA ATTCACTGTT CCTTGCATTC
	TAAAACCTTA

7501	AATACCAGAA AACAGCTTTT TCAAAGTTGT TTTCAAAGTT
	GGCGTATAAC

7551	ATAGTATCGA CGGAGCCGAT TTTGAAACCG CGGTGATCAC
	AGGCAGCAAC

7601	GCTCTGTCAT CGTTACAATC AACATGCTAC CCTCCGCGAG
	ATCATCCGTG

7651	TTTCAAACCC GGCAGCTTAG TTGCCGTTCT TCCGAATAGC
	ATCGGTAACA

7701	TGAGCAAAGT CTGCCGCCTT ACAACGGCTC TCCCGCTGAC
	GCCGTCCCGG

7751	ACTGATGGGC TGCCTGTATC GAGTGGTGAT TTTGTGCCGA
	GCTGCCGGTC

7801	GGGGAGCTGT TGGCTGGCTG GTGGCAGGAT ATATTGTGGT
	GTAAACAAAT

7851	TGACGCTTAG ACAACTTAAT AACACATTGC GGACGTTTTT
	AATGTACTGA

7901	ATTAACGCCG AATTAATTCC TAGGCCACCA TGTTGGGCCC
	GGGGCGCGCC

7951	GTACGTAGTG TTTATCTTTG TTGCTTTTCT GAACAATTTA
	TTTACTATGT

8001	AAATATATTA TCAATGTTTA ATCTATTTTA ATTTGCACAT
	GAATTTTCAT

8051	TTTATTTTTA CTTTACAAAA CAAATAAATA TATATGCAAA
	AAAATTTACA

8101	AACGATGCAC GGGTTACAAA CTAATTTCAT TAAATGCTAA
	TGCAGATTTT

8151	GTGAAGTAAA ACTCCAATTA TGATGAAAAA TACCACCAAC
	ACCACCTGCG

8201	AAACTGTATC CCAACTGTCC TTAATAAAAA TGTTAAAAAG
	TATATTATTC

8251	TCATTTGTCT GTCATAATTT ATGTACCCCA CTTTAATTTT
	TCTGATGTAC

8301	TAAACCGAGG GCAAACTGAA ACCTGTTCCT CATGCAAAGC
	CCCTACTCAC

8351	CATGTATCAT GTACGTGTCA TCACCCAACA ACTCCACTTT
	TGCTATATAA

8401	CAACACCCCC GTCACACTCT CCCTCTCTAA CACACACCCC
	ACTAACAATT

8451	CCTTCACTTG CAGCACTGTT GCATCATCAT CTTCATTGCA
	AAACCCTAAA

8501	CTTCACCTTC AACCGCGGCC GCATGGCTTC TATGATATCC
	TCTTCCGCTG

8551	TGACAACAGT CAGCCGTGCC TCTAGGGGGC AATCCGCCGC
	AGTGGCTCCA

8601	TTCGGCGGCC TCAAATCCAT GACTGGATTC CCAGTGAAGA
	AGGTCAACAC

8651	TGACATTACT TCCATTACAA GCAATGGTGG AAGAGTAAAG
	TGCATGCAGG

8701	TGTGGCCTCC AATTGGAAAG AAGAAGTTTG AGACTCTTTC
	CTATTTGCCA

8751	CCATTGACGA GAGATTCTAG AGTGAGTAAC AAGAACAACG
	ATGAGCTGCA

8801	GTGGCAATCC TGGTTCAGCA AGGCGCCCAC CACCGAGGCG
	AACCCGATGG

8851	CCACCATGTT GCAGGATATC GGCGTTGCGC TCAAACCGGA
	AGCGATGGAG

8901	CAGCTGAAAA ACGATTATCT GCGTGACTTC ACCGCGTTGT
	GGCAGGATTT

8951	TTTGGCTGGC AAGGCGCCAG CCGTCAGCGA CCGCCGCTTC
	AGCTCGGCAG

9001	CCTGGCAGGG CAATCCGATG TCGGCCTTCA ATGCCGCATC
	TTACCTGCTC

9051	AACGCCAAAT TCCTCAGTGC CATGGTGGAG GCGGTGGACA
	CCGCACCCCA

9101	GCAAAAGCAG AAAATACGCT TTGCCGTGCA GCAGGTGATT
	GATGCCATGT

9151	CGCCCGCGAA CTTCCTCGCC ACCAACCCGG AAGCGCAGCA
	AAAACTGATT

9201	GAAACCAAGG GCGAGAGCCT GACGCGTGGC CTGGTCAATA
	TGCTGGGCGA

9251	TATCAACAAG GGCCATATCT CGCTGTCGGA CGAATCGGCC
	TTTGAAGTGG

9301	GCCGCAACCT GGCCATTACC CCGGGCACCG TGATTTACGA
	AAATCCGCTG

9351	TTCCAGCTGA TCCAGTACAC GCCGACCACG CCGACGGTCA
	GCCAGCGCCC

9401	GCTGTTGATG GTGCCGCCGT GCATCAACAA GTTCTACATC
	CTCGACCTGC

9451	AACCGGAAAA TTCGCTGGTG CGCTACGCGG TGGAGCAGGG
	CAACACCGTG

9501	TTCCTGATCT CGTGGAGCAA TCCGGACAAG TCGCTGGCCG
	GCACCACCTG

9551	GGACGACTAC GTGGAGCAGG GCGTGATCGA AGCGATCCGC
	ATCGTCCAGG

9601	ACGTCAGCGG CCAGGACAAG CTGAACATGT TCGGCTTCTG
	CGTGGGCGGC

9651	ACCATCGTTG CCACCGCACT GGCGGTACTG GCGGCGCGTG
	GCCAGCACCC

9701	GGCGGCCAGC CTGACCCTGC TGACCACCTT CCTCGACTTC
	AGCGACACCG

9751	GCGTGCTCGA CGTCTTCGTC GATGAAACCC AGGTCGCGCT
	GCGTGAACAG

9801	CAATTGCGCG ATGGCGGCCT GATGCCGGGC CGTGACCTGG
	CCTCGACCTT

9851	CTCGAGCCTG CGTCCGAACG ACCTGGTATG GAACTATGTG
	CAGTCGAACT

9901	ACCTCAAAGG CAATGAGCCG GCGGCGTTTG ACCTGCTGTT
	CTGGAATTCG

9951	GACAGCACCA ATTTGCCGGG CCCGATGTTC TGCTGGTACC
	TGCGCAACAC

10001	CTACCTGGAA AACAGCCTGA AAGTGCCGGG CAAGCTGACG
	GTGGCCGGCG

10051	AAAAGATCGA CCTCGGCCTG ATCGACGCCC CGGCCTTCAT
	CTACGGTTCG

10101	CGCGAAGACC ACATCGTGCC GTGGATGTCG GCGTACGGTT
	CGCTCGACAT

10151	CCTCAACCAG GGCAAGCCGG GCGCCAACCG CTTCGTGCTG
	GGCGCGTCCG

10201	GCCATATCGC CGGCGTGATC AACTCGGTGG CCAAGAACAA
	GCGCAGCTAC

10251	TGGATCAACG ACGGTGGCGC CGCCGATGCC CAGGCCTGGT
	TCGATGGCGC

10301	GCAGGAAGTG CCGGGCAGCT GGTGGCCGCA ATGGGCCGGG
	TTCCTGACCC

10351	AGCATGGCGG CAAGAAGGTC AAGCCCAAGG CCAAGCCCGG
	CAACGCCCGC

10401	TACACCGCGA TCGAGGCGGC GCCCGGCCGT TACGTCAAAG
	CCAAGGGCTG

10451	AGCGGCCGCT GAGTAATTCT GATATTAGAG GGAGCATTAA
	TGTGTTGTTG

10501	TGATGTGGTT TATATGGGGA AATTAAATAA ATGATGTATG
	TACCTCTTGC

10551	CTATGTAGGT TTGTGTGTTT TGTTTTGTTG TCTAGCTTTG
	GTTATTAAGT

10601	AGTAGGGACG TTCGTTCGTG TCTCAAAAAA AGGGGTACTA
	CCACTCTGTA

10651	GTGTATATGG ATGCTGGAAA TCAATGTGTT TTGTATTTGT
	TCACCTCCAT

10701	TGTTGAATTC AATGTCAAAT GTGTTTTGCG TTGGTTATGT
	GTAAAATTAC

10751	TATCTTTCTC GTCCGATGAT CAAAGTTTTA AGCAACAAAA
	CCAAGGGTGA

10801	AATTTAAACT GTGCTTTGTT GAAGATTCTT TTATCATATT
	GAAAATCAAA

10851	TTACTAGCAG CAGATTTTAC CTAGCATGAA ATTTTATCAA
	CAGTACAGCA

10901	CTCACTAACC AAGTTCCAAA CTAAGATGCG CCATTAACAT
	CAGCCAATAG

10951	GCATTTTCAG CAAGGCGCGC CCGCGCCGAT GTATGTGACA
	ACCCTCGGGA

11001	TTGTTGATTT ATTTCAAAAC TAAGAGTTTT TGTCTTATTG
	TTCTCGTCTA

11051	TTTTGGATAT CAATCTTAGT TTTATATCTT TTCTAGTTCT
	CTACGTGTTA

11101	AATGTTCAAC ACACTAGCAA TTTGGCCTGC CAGCGTATGG
	ATTATGGAAC

11151	TATCAAGTCT GTGACGCGCC GTACGTAGTG TTTATCTTTG
	TTGCTTTTCT

11201	GAACAATTTA TTTACTATGT AAATATATTA TCAATGTTTA
	ATCTATTTTA

11251	ATTTGCACAT GAATTTTCAT TTTATTTTTA CTTTACAAAA
	CAAATAAATA

11301	TATATGCAAA AAAATTTACA AACGATGCAC GGGTTACAAA
	CTAATTTCAT

11351	TAAATGCTAA TGCAGATTTT GTGAAGTAAA ACTCCAATTA
	TGATGAAAAA

11401	TACCACCAAC ACCACCTGCG AAACTGTATC CCAACTGTCC
	TTAATAAAAA

11451	TGTTAAAAAG TATATTATTC TCATTTGTCT GTCATAATTT
	ATGTACCCCA

11501	CTTTAATTTT TCTGATGTAC TAAACCGAGG GCAAACTGAA
	ACCTGTTCCT

11551	CATGCAAAGC CCCTACTCAC CATGTATCAT GTACGTGTCA
	TCACCCAACA

11601	ACTCCACTTT TGCTATATAA CAACACCCCC GTCACACTCT
	CCCTCTCTAA

11651	CACACACCCC ACTAACAATT CCTTCACTTG CAGCACTGTT
	GCATCATCAT

11701	CTTCATTGCA AAACCCTAAA CTTCACCTTC AACCGCGGCC
	GCATGGCTTC

11751	TATGATATCC TCTTCCGCTG TGACAACAGT CAGCCGTGCC
	TCTAGGGGGC

11801	AATCCGCCGC AGTGGCTCCA TTCGGCGGCC TCAAATCCAT
	GACTGGATTC

11851	CCAGTGAAGA AGGTCAACAC TGACATTACT TCCATTACAA
	GCAATGGTGG

11901	AAGAGTAAAG TGCATGCAGG TGTGGCCTCC AATTGGAAAG
	AAGAAGTTTG

11951	AGACTCTTTC CTATTTGCCA CCATTGACGA GAGATTCTAG
	AGTGACTCAG

12001	CGCATTGCGT ATGTGACCGG CGGCATGGGT GGTATCGGAA
	CCGCCATTTG

12051	CCAGCGGCTG GCCAAGGATG GCTTTCGTGT GGTGGCCGGT
	TGCGGCCCCA

12101	ACTCGCCGCG CCGCGAAAAG TGGCTGGAGC AGCAGAAGGC
	CCTGGGCTTC

12151	GATTTCATTG CCTCGGAAGG CAATGTGGCT GACTGGGACT
	CGACCAAGAC

12201	CGCATTCGAC AAGGTCAAGT CCGAGGTCGG CGAGGTTGAT
	GTGCTGATCA

12251	ACAACGCCGG TATCACCCGC GACGTGGTGT TCCGCAAGAT
	GACCCGCGCC

12301	GACTGGGATG CGGTGATCGA CACCAACCTG ACCTCGCTGT
	TCAACGTCAC

12351	CAAGCAGGTG ATCGACGGCA TGGCCGACCG TGGCTGGGGC
	CGCATCGTCA

12401	ACATCTCGTC GGTGAACGGG CAGAAGGGCC AGTTCGGCCA
	GACCAACTAC

12451	TCCACCGCCA AGGCCGGCCT GCATGGCTTC ACCATGGCAC
	TGGCGCAGGA

12501	AGTGGCGACC AAGGGCGTGA CCGTCAACAC GGTCTCTCCG
	GGCTATATCG

12551	CCACCGACAT GGTCAAGGCG ATCCGCCAGG ACGTGCTCGA
	CAAGATCGTC

12601	GCGACGATCC CGGTCAAGCG CCTGGGCCTG CCGGAAGAGA
	TCGCCTCGAT

12651	CTGCGCCTGG TTGTCGTCGG AGGAGTCCGG TTTCTCGACC
	GGCGCCGACT

12701	TCTCGCTCAA CGGCGGCCTG CATATGGGCT GAGCGGCCGC
	TGAGTAATTC

12751	TGATATTAGA GGGAGCATTA ATGTGTTGTT GTGATGTGGT
	TTATATGGGG

12801	AAATTAAATA AATGATGTAT GTACCTCTTG CCTATGTAGG
	TTTGTGTGTT

12851	TTGTTTTGTT GTCTAGCTTT GGTTATTAAG TAGTAGGGAC
	GTTCGTTCGT

12901	GTCTCAAAAA AAGGGGTACT ACCACTCTGT AGTGTATATG
	GATGCTGGAA

12951	ATCAATGTGT TTTGTATTTG TTCACCTCCA TTGTTGAATT
	CAATGTCAAA

13001	TGTGTTTTGC GTTGGTTATG TGTAAAATTA CTATCTTTCT
	CGTCCGATGA

13051	TCAAAGTTTT AAGCAACAAA ACCAAGGGTG AAATTTAAAC
	TGTGCTTTGT

13101	TGAAGATTCT TTTATCATAT TGAAAATCAA ATTACTAGCA
	GCAGATTTTA

13151	CCTAGCATGA AATTTTATCA ACAGTACAGC ACTCACTAAC
	CAAGTTCCAA

13201	ACTAAGATGC GCCATTAACA TCAGCCAATA GGCATTTTCA
	GCAAGGCGCG

13251	TAAGGGGATC CGTACGTAAG TACGTACTCA AAATGCCAAC
	AAATAAAAAA

13301	AAAGTTGCTT TAATAATGCC AAAACAAATT AATAAAACAC
	TTACAACACC

13351	GGATTTTTTT TAATTAAAAT GTGCCATTTA GGATAAATAG
	TTAATATTTT

13401	TAATAATTAT TTAAAAAGCC GTATCTACTA AAATGATTTT
	TATTTGGTTG

13451	AAAATATTAA TATGTTTAAA TCAACACAAT CTATCAAAAT
	TAAACTAAAA

13501	AAAAAATAAG TGTACGTGGT TAACATTAGT ACAGTAATAT
	AAGAGGAAAA

13551	TGAGAAATTA AGAAATTGAA AGCGAGTCTA ATTTTTAAAT
	TATGAACCTG

13601	CATATATAAA AGGAAAGAAA GAATCCAGGA AGAAAAGAAA
	TGAAACCATG

13651	CATGGTCCCC TCGTCATCAC GAGTTTCTGC CATTTGCAAT
	AGAAACACTG

13701	AAACACCTTT CTCTTTGTCA CTTAATTGAG ATGCCGAAGC
	CACCTCACAC

13751	CATGAACTTC ATGAGGTGTA GCACCCAAGG CTTCCATAGC
	CATGCATACT

13801	GAAGAATGTC TCAAGCTCAG CACCCTACTT CTGTGACGTG
	TCCCTCATTC

13851	ACCTTCCTCT CTTCCCTATA AATAACCACG CCTCAGGTTC
	TCCGCTTCAC

13901	AACTCAAACA TTCTCTCCAT TGGTCCTTAA ACACTCATCA
	GTCATCACCG

13951	CGGCCGCGGA ATTCATGGCT TCTATGATAT CCTCTTCCGC
	TGTGACAACA

14001	GTCAGCCGTG CCTCTAGGGG GCAATCCGCC GCAGTGGCTC
	CATTCGGCGG

14051	CCTCAAATCC ATGACTGGAT TCCCAGTGAA GAAGGTCAAC
	ACTGACATTA

14101	CTTCCATTAC AAGCAATGGT GGAAGAGTAA AGTGCATGCA
	GGTGTGGCCT

14151	CCAATTGGAA AGAAGAAGTT TGAGACTCTT TCCTATTTGC
	CACCATTGAC

14201	GAGAGATTCT AGAGTGACTG ACGTTGTCAT CGTATCCGCC
	GCCCGCACCG

14251	CGGTCGGCAA GTTTGGCGGC TCGCTGGCCA AGATCCCGGC
	ACCGGAACTG

14301	GGTGCCGTGG TCATCAAGGC CGCGCTGGAG CGCGCCGGCG
	TCAAGCCGGA

14351	GCAGGTGAGC GAAGTCATCA TGGGCCAGGT GCTGACCGCC
	GGTTCGGGCC

14401	AGAACCCCGC ACGCCAGGCC GCGATCAAGG CCGGCCTGCC
	GGCGATGGTG

14451	CCGGCCATGA CCATCAACAA GGTGTGCGGC TCGGGCCTGA
	AGGCCGTGAT

14501	GCTGGCCGCC AACGCGATCA TGGCGGGCGA CGCCGAGATC
	GTGGTGGCCG

14551	GCGGCCAGGA AAACATGAGC GCCGCCCCGC ACGTGCTGCC
	GGGCTCGCGC

14601	GATGGTTTCC GCATGGGCGA TGCCAAGCTG GTCGACACCA
	TGATCGTCGA

14651	CGGCCTGTGG GACGTGTACA ACCAGTACCA CATGGGCATC
	ACCGCCGAGA

14701	ACGTGGCCAA GGAATACGGC ATCACACGCG AGGCGCAGGA
	TGAGTTCGCC

14751	GTCGGCTCGC AGAACAAGGC CGAAGCCGCG CAGAAGGCCG
	GCAAGTTTGA

14801	CGAAGAGATC GTCCCGGTGC TGATCCCGCA GCGCAAGGGC
	GACCCGGTGG

14851	CCTTCAAGAC CGACGAGTTC GTGCGCCAGG GCGCCACGCT
	GGACAGCATG

14901	TCCGGCCTCA AGCCCGCCTT CGACAAGGCC GGCACGGTGA
	CCGCGGCCAA

14951	CGCCTCGGGC CTGAACGACG GCGCCGCCGC GGTGGTGGTG
	ATGTCGGCGG

15001	CCAAGGCCAA GGAACTGGGC CTGACCCCGC TGGCCACGAT
	CAAGAGCTAT

15051	GCCAACGCCG GTGTCGATCC CAAGGTGATG GGCATGGGCC
	CGGTGCCGGC

15101	CTCCAAGCGC GCCCTGTCGC GCGCCGAGTG GACCCCGCAA
	GACCTGGACC

15151	TGATGGAGAT CAACGAGGCC TTTGCCGCGC AGGCGCTGGC
	GGTGCACCAG

15201	CAGATGGGCT GGGACACCTC CAAGGTCAAT GTGAACGGCG
	GCGCCATCGC

15251	CATCGGCCAC CCGATCGGCG CGTCGGGCTG CCGTATCCTG
	GTGACGCTGC

15301	TGCACGAGAT GAAGCGCCGT GACGCGAAGA AGGGCCTGGC
	CTCGCTGTGC

15351	ATCGGCGGCG GCATGGGCGT GGCGCTGGCA GTCGAGCGCA
	AATAACTCGA

15401	GGCGGCCGCA GCCCTTTTTG TATGTGCTAC CCCACTTTTG
	TCTTTTTGGC

15451	AATAGTGCTA GCAACCAATA AATAATAATA ATAATAATGA
	ATAAGAAAAC

15501	AAAGGCTTTA GCTTGCCTTT TGTTCACTGT AAAATAATAA
	TGTAAGTACT

15551	CTCTATAATG AGTCACGAAA CTTTTGCGGG AATAAAAGGA
	GAAATTCCAA

15601	TGAGTTTTCT GTCAAATCTT CTTTTGTCTC TCTCTCTCTC
	TCTTTTTTTT

15651	TTTTCTTTCT TCTGAGCTTC TTGCAAAACA AAAGGCAAAC
	AATAACGATT

15701	GGTCCAATGA TAGTTAGCTT GATCGATGAT ATCTTTAGGA
	AGTGTTGGCA

15751	GGACAGGACA TGATGTAGAA GACTAAAATT GAAAGTATTG
	CAGACCCAAT

15801	AGTTGAAGAT TAACTTTAAG AATGAAGACG TCTTATCAGG
	TTCTTCATGA

15851	CTTAAGCTTT AAGAGGAGTC CACCATGGTA GATCTGACTA
	GTGATCCGTA

15901	CGTAAGTACG TACTCAAAAT GCCAACAAAT AAAAAAAAAG
	TTGCTTTAAT

15951	AATGCCAAAA CAAATTAATA AAACACTTAC AACACCGGAT
	TTTTTTTAAT

16001	TAAAATGTGC CATTTAGGAT AAATAGTTAA TATTTTTAAT
	AATTATTTAA

16051	AAAGCCGTAT CTACTAAAAT GATTTTTATT TGGTTGAAAA
	TATTAATATG

16101	TTTAAATCAA CACAATCTAT CAAAATTAAA CTAAAAAAAA
	AATAAGTGTA

16151	CGTGGTTAAC ATTAGTACAG TAATATAAGA GGAAAATGAG
	AAATTAAGAA

16201	ATTGAAAGCG AGTCTAATTT TTAAATTATG AACCTGCATA
	TATAAAAGGA

16251	AAGAAAGAAT CCAGGAAGAA AAGAAATGAA ACCATGCATG
	GTCCCCTCGT

16301	CATCACGAGT TTCTGCCATT TGCAATAGAA ACACTGAAAC
	ACCTTTCTCT

16351	TTGTCACTTA ATTGAGATGC CGAAGCCACC TCACACCATG
	AACTTCATGA

16401	GGTGTAGCAC CCAAGGCTTC CATAGCCATG CATACTGAAG
	AATGTCTCAA

16451	GCTCAGCACC CTACTTCTGT GACGTGTCCC TCATTCACCT
	TCCTCTCTTC

16501	CCTATAAATA ACCACGCCTC AGGTTCTCCG CTTCACAACT
	CAAACATTCT

16551	CTCCATTGGT CCTTAAACAC TCATCAGTCA TCACCATGGA
	CTCCAAAGAA

16601	TCATTAACTC CTGGTAGAGA AGAAAACCCC AGCAGTGTGC
	TTGCTCAGGA

16651	GAGGGGAGAT GTGATGGACT TCTATAAAAC CCTAAGAGGA
	GGAGCTACTG

16701	TGAAGGTTTC TGCGTCTTCA CCCTCACTGG CTGTCGCTTC
	TCAATCAGAC

16751	TCCAAGCAGC GAAGACTTTT GGTTGATTTT CCAAAAGGCT
	CAGTAAGCAA

16801	TGCGCAGCAG CCAGATCTGT CCAAAGCAGT TTCACTCTCA
	ATGGGACTGT

16851	ATATGGGAGA GACAGAAACA AAAGTGATGG GAAATGACCT
	GGGATTCCCA

16901	CAGCAGGGCC AAATCAGCCT TTCCTCGGGG GAAACAGACT
	TAAAGCTTTT

16951	GGAAGAAAGC ATTGCAAACC TCAATAGGTC GACCAGTGTT
	CCAGAGAACC

17001	CCAAGAGTTC AGCATCCACT GCTGTGTCTG CTGCCCCCAC
	AGCTAGTTCT

17051	GCGGCCCCCC CGACCGATGT CAGCCTGGGG GACGAGCTCC
	ACTTAGACGG

17101	CGAGGACGTG GCGATGGCGC ATGCCGACGC GCTAGACGAT
	TTCGATCTGG

17151	ACATGTTGGG GGACGGGGAT TCCCCGGGTC CGGGATTTAC
	CCCCCACGAC

17201	TCCGCCCCCT ACGGCGCTCT GGATATGGCC GACTTCGAGT
	TTGAGCAGAT

17251	GTTTACCGAT GCCCTTGGAA TTGACGAGTA CGGTGGGACT
	AGCTCCAGCT

17301	CCTCAACAGC AACAACAGGA CCACCTCCCA AACTCTGCCT
	GGTGTGCTCT

17351	GATGAAGCTT CAGGATGTCA TTATGGAGTC TTAACTTGTG
	GAAGCTGTAA

17401	AGTTTTCTTC AAAAGAGCAG TGGAAGGACA GCACAATTAC
	CTATGTGCTG

17451	GAAGGAATGA TTGCATCATC GATAAAATTC GAAGAAAAAA
	CTGCCCAGCA

17501	TGCCGCTATC GAAAATGTCT TCAGGCTGGA ATGAACCTGG
	AAGCTCGAAA

17551	AACAAAGAAA AAAATAAAAG GAATTGCTCG ACAAAGGCCC
	GAGTGCGTGG

17601	TGCCGGAGAA CCAGTGTGCA ATGAAACGGA AAGAGAAAAA
	GGCGCAGAGG

17651	GAAAAAGACA AATTGCCCGT CAGTACGACG ACAGTAGACG
	ATCACATGCC

17701	TCCCATCATG CAATGTGACC CTCCGCCCCC AGAGGCCGCT
	AGAATTCTGG

17751	AATGTTTGCA GCACGAGGTG GTGCCACGAT TCCTGAATGA
	GAAGCTAATG

17801	GAACAGAACA GATTGAAGAA CGTGCCCCCC CTCACTGCCA
	ATCAGAAGTC

17851	GTTGATCGCA AGGCTCGTGT GGTACCAGGA AGGCTATGAA
	CAACCTTCCG

17901	AGGAAGACCT GAAGAGGGTT ACACAGTCGG ACGAGGACGA
	CGAAGACTCG

17951	GATATGCCGT TCCGTCAGAT TACCGAGATG ACGATTCTCA
	CAGTGCAGCT

18001	CATCGTAGAA TTCGCTAAGG GCCTCCCGGG CTTCGCCAAG
	ATCTCGCAGT

18051	CGGACCAGAT CACGTTATTA AAGGCGTGCT CAAGTGAGGT
	GATGATGCTC

18101	CGAGTGGCTC GGCGGTATGA CGCGGCCACC GACAGCGTAC
	TGTTCGCGAA

18151	CAACCAGGCG TACACTCGCG ACAACTACCG CAAGGCAGGC
	ATGGCGTACG

18201	TCATCGAGGA CCTGCTGCAC TTCTGTCGGT GCATGTACTC
	CATGATGATG

18251	GATAACGTGC ATTATGCGCT GCTTACAGCC ATTGTCATCT
	TCTCAGACCG

18301	GCCCGGGCTT GAGCAACCCC TGTTGGTGGA GGAGATCCAG
	AGATATTACC

18351	TGAACACGCT ACGGGTGTAC ATCCTGAACC AGAACAGCGC
	GTCGCCCCGC

18401	TGCGCCGTCA TCTTCGGCAA GATCCTGGGC ATACTGACGG
	AGATCCGCAC

18451	GCTGGGCATG CAGAACTCCA ACATGTGCAT CTCCCTCAAG
	CTGAAGAACA

18501	GGAAGCTGCC GCCGTTCCTC GAGGAGATCT GGGACGTGGC
	GGACGTGGCG

18551	ACGACGGCGA CGCCGGTGGC GGCGGAGGCG CCGGCGCTCT
	AGCCCCCGCG

18601	CCGCCCGCCC GGCCGCGCGC ACGTCTAGCG CGCCTCAGGA
	GAGAACGCTC

18651	ATAGACTGGC TAGTTTTAGT GAAGTGCACG GACACTGACG
	TCGGACGTGA

18701	TCAACCTATT TATAAGGACT GCGAATTTTA CCACTTAAGA
	GGGCACACCC

18751	GTACCCGATT TCGTACGGGA ATTCCTGCAG CCCGGGGGAT
	CCTTAATTAA

18801	CTCGAGGAAT TCATCGATTC CGCGGGTACC GAGCTCGATC
	CGTCGACCTG

18851	CAGATCGTTC AAACATTTGG CAATAAAGTT TCTTAAGATT
	GAATCCTGTT

18901	GCCGGTCTTG CGATGATTAT CATATAATTT CTGTTGAATT
	AGGTTAAGCA

18951	TGTAATAATT AACATGTAAT GCATGACGTT ATTTATGAGA
	TGGGTTTTTA

19001	TGATTAGAGT CCCGCAATTA TACATTTAAT ACGCGATAGA
	AAACAAAATA

19051	TAGCGCGCAA ACTAGGATAA ATTATCGCGC GCGGTGTCAT
	CTATGTTACT

19101	AGATCTGGCG CGCCCCTAGG TCTAGAGTCG ACTGTTTAAA
	CGGTCCGTGA

19151	CCATGATTAC GCCAAGCTTC GACTGTACAG GATGTTCTAG
	CTACTCGAGT

19201	AGCTAGAACA TCCTGTACAG TCGAGTAGCT AGAACATCCT
	GTACAGTCGA

19251	CTAGCTAGAA CATCCTGTAC AGTCGAGTAG CTAGAACATC
	CTGTACAGTC

19301	GAGTAGCTAG ACATCCTGTA CAGGATCCCT ATATAAGGAA
	GTTCATTTCA

19351	TTTGGAGAGA ACACGGGGGA TCGGGTATCG TTAATTAAGT
	TTATCAACAA

19401	GTTTGTACAA AAAAGCAGGC TCCGCGGCCG CCCCCTTCAC
	CATGATCGTC

19451	GACGGCCTGT GGGACGTGTA CAACCAGTAC CACATGGGCA
	TCACCGCCGA

19501	GAACGTGGCC AAGGAATACG GCATCACACG CGAGGCGCAG
	GATGAGTTCG

19551	CCGTCGGCTC GCAGAACAAG GCCGAAGCCG CGCAGAAGGC
	CGGCAAGTTT

19601	GACGAAGAGA TCGTCCCGGT GCTGATCCCG CAGCGCAAGG
	GCGACCCGGT

19651	GGCCTTCAAG ACCGACGAGT TCGTGCGCCA GGGCGCCACG
	CTGGACAGCA

19701	TGTCCGGCCT CAAGCCCGCC TTCGACAAGG CCGGCACGGT
	GACCGCGGCC

19751	AACGCCTCGG GCCTGAACGA CGGCGCCGCC GCGGTGGTGG
	TGATGTCGGC

19801	GGCCAAGGCC AAGGAACTGG GCCTGACCCC GCTGGCCACG
	ATCAAGAGCT

19851	ATGCCAACGC CGGTGTCGAT CCCAAGGTGA TGGGCATGGG
	CCCGGTGCCG

19901	GCCTCCAAGC GCGCCCTGTC GCGCGCCGAG TGGACCCCGC
	AAGACCTGGA

19951	CCTGATGGAG ATCAACGAGG CCTTTGCCGC GCAGGCGCTG
	GCGGTGCACC

20001	AGCAGATGGG CTGGGACACC TCCAAGGTCA ATGTGAAAGG
	GTGGGCGCGC

20051	CGACCCAGCT TTCTTGTACA AAGTGGTTGA TCCTGCAGGG
	TCCGTCGCTT

20101	CTCTTCCATT TCTTCTCATT TTCGATTTTG ATTCTTATTT
	CTTTCCAGTA

20151	GCTCCTGCTC TGTGAATTTC TCCGCTCACG ATAGATCTGC
	TTATACTCCT

20201	TACATTCAAC CTTAGATCTG GTCTCGATTC TCTGTTTCTC
	TGTTTTTTTC

20251	TTTTGGTCGA GAATCTGATG TTTGTTTATG TTCTGTCACC
	ATTAATAATA

20301	ATGAACTCTC TCATTCATAC AATGATTAGT TTCTCTCGTC
	TACAAAACGA

20351	TATGTTGCAT TTTCACTTTT CTTCTTTTTT TCTAAGATGA
	TTTGCTTTGA

20401	CCAATTTGTT TAGATCTTTA TTCTATTTTA TTTTCTGGTG
	GGTTGGTGGA

20451	AATTGAAAAA AAAAAAACAG CATAAATTGT TATTTGTTAA
	TGTATTCATT

20501	TTTTGGCTAT TTGTTCTGGG TAAAAATCTG CTTCTACTAT
	TGAATCTTTC

20551	CTGGATTTTT TACTCCTATT GGGTTTTTAT AGTAAAAATA
	CATAATAAAA

20601	GGAAAACAAA AGTTTTATAG ATTCTCTTAA ACCCCTTACG
	ATAAAAGTTG

20651	GAATCAAAAT AATTCAGGAT CAGATGCTCT TTGATTGATT
	CAGATGCGAT

20701	TACAGTTGCA TGGCAAATTT TCTAGATCCG TCGTCACATT
	TTATTTTCTG

20751	TTTAAATATC TAAATCTGAT ATATGATGTC GACAAATTCT
	GGTGGCTTAT

20801	ACATCACTTC AACTGTTTTC TTTTGGCTTT GTTTGTCAAC
	TTGGTTTTCA

20851	ATACGATTTG TGATTTCGAT CGCTGAATTT TTAATACAAG
	CAAACTGATG

20901	TTAACCACAA GCAAGAGATG TGACCTGCCT TATTAACATC
	GTATTACTTA

20951	CTACTAGTCG TATTCTCAAC GCAATCGTTT TTGTATTTCT
	CACATTATGC

21001	CGCTTCTCTA CTCTTTATTC CTTTTGGTCC ACGCATTTTC
	TATTTGTGGC

21051	AATCCCTTTC ACAACCTGAT TTCCCACTTT GGATCATTTG
	TCTGAAGACT

21101	CTCTTGAATC GTTACCACTT GTTTCTTGTG CATGCTCTGT
	TTTTTAGAAT

21151	TAATGATAAA ACTATTCCAT AGTCTTGAGT TTTCAGCTTG
	TTGATTCTTT

21201	TGCTTTTGGT TTTCTGCAGG TTTAAACATC AACCACTTTG
	TACAAGAAAG

21251	CTGGGTCGGC GCGCCCACCC TTTCACATTG ACCTTGGAGG
	TGTCCCAGCC

21301	CATCTGCTGG TGCACCGCCA GCGCCTGCGC GGCAAAGGCC
	TCGTTGATCT

21351	CCATCAGGTC CAGGTCTTGC GGGGTCCACT CGGCGCGCGA
	CAGGGCGCGC

21401	TTGGAGGCCG GCACCGGGCC CATGCCCATC ACCTTGGGAT
	CGACACCGGC

21451	GTTGGCATAG CTCTTGATCG TGGCCAGCGG GGTCAGGCCC
	AGTTCCTTGG

21501	CCTTGGCCGC CGACATCACC ACCACCGCGG CGGCGCCGTC
	GTTCAGGCCC

21551	GAGGCGTTGG CCGCGGTCAC CGTGCCGGCC TTGTCGAAGG
	CGGGCTTGAG

21601	GCCGGACATG CTGTCCAGCG TGGCGCCCTG GCGCACGAAC
	TCGTCGGTCT

21651	TGAAGGCCAC CGGGTCGCCC TTGCGCTGCG GGATCAGCAC
	CGGGACGATC

21701	TCTTCGTCAA ACTTGCCGGC CTTCTGCGCG GCTTCGGCCT
	TGTTCTGCGA

21751	GCCGACGGCG AACTCATCCT GCGCCTCGCG TGTGATGCCG
	TATTCCTTGG

21801	CCACGTTCTC GGCGGTGATG CCCATGTGGT ACTGGTTGTA
	CACGTCCCAC

21851	AGGCCGTCGA CGATCATGGT GAAGGGGGCG GCCGCGGAGC
	CTGCTTTTTT

21901	GTACAAACTT GTTGATCTCG AGCGGCGCGC CGTTCGAGTA
	TTATGGCATT

21951	GGGAAAACTG TTTTTCTTGT ACCATTTGTT GTGCTTGTAA
	TTTACTGTGT

22001	TTTTTATTCG GTTTTCGCTA TCGAACTGTG AAATGGAAAT
	GGATGGAGAA

22051	GAGTTAATGA ATGATATGGT CCTTTTGTTC ATTCTCAAAT
	TAATATTATT

22101	TGTTTTTTCT CTTATTTGTT GTGTGTTGAA TTTGAAATTA
	TAAGAGATAT

22151	GCAAACATTT TGTTTTGAGT AAAAATGTGT CAAATCGTGG
	CCTCTAATGA

22201	CCGAAGTTAA TATGAGGAGT AAAACACTGT TTAAACCCTG
	CAGGATTT

Vector: pPhaC-RNAi/glyP

(SEQ ID NO: 6)

1	GTCCGTGACC ATGATTACGC CAAGCTTCGA CTGTACAGGA
	TGTTCTAGCT

51	ACTCGAGTAG CTAGAACATC CTGTACAGTC GAGTAGCTAG
	AACATCCTGT

101	ACAGTCGACT AGCTAGAACA TCCTGTACAG TCGAGTAGCT
	AGAACATCCT

151	GTACAGTCGA GTAGCTAGAC ATCCTGTACA GGATCCCTAT
	ATAAGGAAGT

201	TCATTTCATT TGGAGAGAAC ACGGGGGATC GGGTATCGTT
	AATTAAGTTT

251	ATCAACAAGT TTGTACAAAA AAGCAGGCTC CGCGGCCGCC
	CCCTTCACCT

301	TCCTCGACTT CAGCGACACC GGCGTGCTCG ACGTCTTCGT
	CGATGAAACC

351	CAGGTCGCGC TGCGTGAACA GCAATTGCGC GATGGCGGCC
	TGATGCCGGG

401	CCGTGACCTG GCCTCGACCT TCTCGAGCCT GCGTCCGAAC
	GACCTGGTAT

451	GGAACTATGT GCAGTCGAAC TACCTCAAAG GCAATGAGCC
	GGCGGCGTTT

501	GACCTGCTGT TCTGGAATTC GGACAGCACC AATTTGCCGG
	GCCCGATGTT

551	CTGCTGGTAC CTGCGCAACA CCTACCTGGA AAACAGCCTG
	AAAGTGCCGG

601	GCAAGCTGAC GGTGGCCGGC GAAAAGATCG ACCTCGGCCT
	GATCGACGCC

651	CCGGCCTTCA TCTACGGTTC GCGCGAAGAC CACATCGTGC
	CGTGGATGTC

701	GGCGTACGGT TCGCTCGACA TCCTCAACCA GGGCAAGCCG
	GGCGCCAACC

751	GCTTCGTGCT GGGCGCGTCC GGCCATATCG CCGGCGTGAT
	CAACTCGGTG

801	GCCAAGAACA AGCGCAGCTA CTGGATCAAC GACGGTGGCG
	CCGCCGATGC

851	CCAGGCCTGG TTCGATGGCG CGCAGGAAGT GCCGGGCAGC
	TGGTGGCCGC

901	AATGGGCCGG GTTCCTGACC CAGCATGGCG GCAAGAAGGT
	CAAGCCCAAG

951	GCCAAAAGGG TGGGCGCGCC GACCCAGCTT TCTTGTACAA
	AGTGGTTGAT

1001	CCTGCAGGGT CCGTCGCTTC TCTTCCATTT CTTCTCATTT
	TCGATTTTGA

1051	TTCTTATTTC TTTCCAGTAG CTCCTGCTCT GTGAATTTCT
	CCGCTCACGA

1101	TAGATCTGCT TATACTCCTT ACATTCAACC TTAGATCTGG
	TCTCGATTCT

1151	CTGTTTCTCT GTTTTTTTCT TTTGGTCGAG AATCTGATGT
	TTGTTTATGT

1201	TCTGTCACCA TTAATAATAA TGAACTCTCT CATTCATACA
	ATGATTAGTT

1251	TCTCTCGTCT ACAAAACGAT ATGTTGCATT TTCACTTTTC
	TTCTTTTTTT

1301	CTAAGATGAT TTGCTTTGAC CAATTTGTTT AGATCTTTAT
	TCTATTTTAT

1351	TTTCTGGTGG GTTGGTGGAA ATTGAAAAAA AAAAAACAGC
	ATAAATTGTT

1401	ATTTGTTAAT GTATTCATTT TTTGGCTATT TGTTCTGGGT
	AAAAATCTGC

1451	TTCTACTATT GAATCTTTCC TGGATTTTTT ACTCCTATTG
	GGTTTTTATA

1501	GTAAAAATAC ATAATAAAAG GAAAACAAAA GTTTTATAGA
	TTCTCTTAAA

1551	CCCCTTACGA TAAAAGTTGG AATCAAAATA ATTCAGGATC
	AGATGCTCTT

1601	TGATTGATTC AGATGCGATT ACAGTTGCAT GGCAAATTTT
	CTAGATCCGT

1651	CGTCACATTT TATTTTCTGT TTAAATATCT AAATCTGATA
	TATGATGTCG

1701	ACAAATTCTG GTGGCTTATA CATCACTTCA ACTGTTTTCT
	TTTGGCTTTG

1751	TTTGTCAACT TGGTTTTCAA TACGATTTGT GATTTCGATC
	GCTGAATTTT

1801	TAATACAAGC AAACTGATGT TAACCACAAG CAAGAGATGT
	GACCTGCCTT

1851	ATTAACATCG TATTACTTAC TACTAGTCGT ATTCTCAACG
	CAATCGTTTT

1901	TGTATTTCTC ACATTATGCC GCTTCTCTAC TCTTTATTCC
	TTTTGGTCCA

1951	CGCATTTTCT ATTTGTGGCA ATCCCTTTCA CAACCTGATT
	TCCCACTTTG

2001	GATCATTTGT CTGAAGACTC TCTTGAATCG TTACCACTTG
	TTTCTTGTGC

2051	ATGCTCTGTT TTTTAGAATT AATGATAAAA CTATTCCATA
	GTCTTGAGTT

2101	TTCAGCTTGT TGATTCTTTT GCTTTTGGTT TTCTGCAGGT
	TTAAACATCA

2151	ACCACTTTGT ACAAGAAAGC TGGGTCGGCG CGCCCACCCT
	TTTGGCCTTG

2201	GGCTTGACCT TCTTGCCGCC ATGCTGGGTC AGGAACCCGG
	CCCATTGCGG

2251	CCACCAGCTG CCCGGCACTT CCTGCGCGCC ATCGAACCAG
	GCCTGGGCAT

2301	CGGCGGCGCC ACCGTCGTTG ATCCAGTAGC TGCGCTTGTT
	CTTGGCCACC

2351	GAGTTGATCA CGCCGGCGAT ATGGCCGGAC GCGCCCAGCA
	CGAAGCGGTT

2401	GGCGCCCGGC TTGCCCTGGT TGAGGATGTC GAGCGAACCG
	TACGCCGACA

2451	TCCACGGCAC GATGTGGTCT TCGCGCGAAC CGTAGATGAA
	GGCCGGGGCG

2501	TCGATCAGGC CGAGGTCGAT CTTTTCGCCG GCCACCGTCA
	GCTTGCCCGG

2551	CACTTTCAGG CTGTTTTCCA GGTAGGTGTT GCGCAGGTAC
	CAGCAGAACA

2601	TCGGGCCCGG CAAATTGGTG CTGTCCGAAT TCCAGAACAG
	CAGGTCAAAC

2651	GCCGCCGGCT CATTGCCTTT GAGGTAGTTC GACTGCACAT
	AGTTCCATAC

2701	CAGGTCGTTC GGACGCAGGC TCGAGAAGGT CGAGGCCAGG
	TCACGGCCCG

2751	GCATCAGGCC GCCATCGCGC AATTTCTGTT CACGCAGCGC
	GACCTGGGTT

2801	TCATCGACGA AGACGTCGAG CACGCCGGTG TCGCTGAAGT
	CGAGGAAGGT

2851	GAAGGGGGCG GCCGCGGAGC CTGCTTTTTT GTACAAACTT
	GTTGATCTCG

2901	AGCGGCGCGC CGTTCGAGTA TTATGGCATT GGGAAAACTG
	TTTTTCTTGT

2951	ACCATTTGTT GTGCTTGTAA TTTACTGTGT TTTTTATTCG
	GTTTTCGCTA

3001	TCGAACTGTG AAATGGAAAT GGATGGAGAA GAGTTAATGA
	ATGATATGGT

3051	CCTTTTGTTC ATTCTCAAAT TAATATTATT TGTTTTTTCT
	CTTATTTGTT

3101	GTGTGTTGAA TTTGAAATTA TAAGAGATAT GCAAACATTT
	TGTTTTGAGT

3151	AAAAATGTGT CAAATCGTGG CCTCTAATGA CCGAAGTTAA
	TATGAGGAGT

3201	AAAACACTGT TTAAACCCTG CAGGATTTAA ATAGAAGGTA
	ATTATCCAAG

3251	ATGTAGCATC AAGAATCCAA TGTTTACGGG AAAAACTATG
	GAAGTATTAT

3301	GTGAGCTCAG CAAGAAGGAG ATCAATATGC GGCACATATG
	CAACCTATGT

3351	TCAAAAATGA AGAATGTACA GATACAAGAT CCTATACTGC
	CAGAATACGA

3401	AGAAGAATAC GTAGAAATTG AAAAAGAAGA ACCAGGCGAA
	GAAAAGAATC

3451	TTGAAGACGT AAGCACTGAC GACAACAATG AAAAGAAGAA
	GATAAGGTCG

3501	GTGATTGTGA AAGAGACATA GAGGACACAT GTAAGGTGGA
	AAATGTAAGG

3551	GCGGAAAGTA ACCTTATCAC AAAGGAATCT TATCCCCCAC
	TACTTATCCT

3601	TTTATATTTT TCCGTGTCAT TTTTGCCCTT GAGTTTTCCT
	ATATAAGGAA

3651	CCAAGTTCGG CATTTGTGAA AACAAGAAAA AATTGGTGTA
	AGCTATTTTC

3701	TTTGAAGTAC TGAGGATACA ACTTCAGAGA AATTTGTAAG
	AAAGTGGATC

3751	GAAACCATGG CCTCCTCCGA GAACGTCATC ACCGAGTTCA
	TGCGCTTCAA

3801	GGTGCGCATG GAGGGCACCG TGAACGGCCA CGAGTTCGAG
	ATCGAGGGCG

3851	AGGGCGAGGG CCGCCCCTAC GAGGGCCACA ACACCGTGAA
	GCTGAAGGTG

3901	ACCAAGGGCG GCCCCCTGCC CTTCGCCTGG GACATCCTGT
	CCCCCCAGTT

3951	CCAGTACGGC TCCAAGGTGT ACGTGAAGCA CCCCGCCGAC
	ATCCCCGACT

4001	ACAAGAAGCT GTCCTTCCCC GAGGGCTTCA AGTGGGAGCG
	CGTGATGAAC

4051	TTCGAGGACG GCGGCGTGGC GACCGTGACC CAGGACTCCT
	CCCTGCAGGA

4101	CGGCTGCTTC ATCTACAAGG TGAAGTTCAT CGGCGTGAAC
	TTCCCCTCCG

4151	ACGGCCCCGT GATGCAGAAG AAGACCATGG GCTGGGAGGC
	CTCCACCGAG

4201	CGCCTGTACC CCCGCGACGG CGTGCTGAAG GGCGAGACCC
	ACAAGGCCCT

4251	GAAGCTGAAG GACGGCGGCC ACTACCTGGT GGAGTTCAAG
	TCCATCTACA

4301	TGGCCAAGAA GCCCGTGCAG CTGCCCGGCT ACTACTACGT
	GGACGCCAAG

4351	CTGGACATCA CCTCCCACAA CGAGGACTAC ACCATCGTGG
	AGCAGTACGA

4401	GCGCACCGAG GGCCGCCACC ACCTGTTCCT GGTACCAATG
	AGCTCTGTCC

4451	AACAGTCTCA GGGTTAATGT CTATGTATCT TAAATAATGT
	TGTCGGCGAT

4501	CGTTCAAACA TTTGGCAATA AAGTTTCTTA AGATTGAATC
	CTGTTGCCGG

4551	TCTTGCGATG ATTATCATAT AATTTCTGTT GAATTACGTT
	AAGCATGTAA

4601	TAATTAACAT GTAATGCATG ACGTTATTTA TGAGATGGGT
	TTTTATGATT

4651	AGAGTCCCGC AATTATACAT TTAATACGCG ATAGAAAACA
	AAATATAGCG

4701	CGCAAACTAG GATAAATTAT CGCGCGCGGT GTCATCTATG
	TTACTAGATC

4751	GGGAATTAAA CTATCAGTGT TTGACAGGAT ATATTGGCGG
	GTAAACCTAA

4801	GAGAAAAGAG CGTTTATTAG AATAACGGAT ATTTAAAAGG
	GCGTGAAAAG

4851	GTTTATCCGT TCGTCCATTT GTATGTGCAT GCCAACCACA
	GGGTTCCCCT

4901	CGGGATCAAA GTACTTTGAT CCAACCCCTC CGCTGCTATA
	GTGCAGTCGG

4951	CTTCTGACGT TCAGTGCAGC CGTCTTCTGA AAACGACATG
	TCGCACAAGT

5001	CCTAAGTTAC GCGACAGGCT GCCGCCCTGC CCTTTTCCTG
	GCGTTTTCTT

5051	GTCGCGTGTT TTAGTCGCAT AAAGTAGAAT ACTTGCGACT
	AGAACCGGAG

5101	ACATTACGCC ATGAACAAGA GCGCCGCCGC TGGCCTGCTG
	GGCTATGCCC

5151	GCGTCAGCAC CGACGACCAG GACTTGACCA ACCAACGGGC
	CGAACTGCAC

5201	GCGGCCGGCT GCACCAAGCT GTTTTCCGAG AAGATCACCG
	GCACCAGGCG

5251	CGACCGCCCG GAGCTGGCCA GGATGCTTGA CCACCTACGC
	CCTGGCGACG

5301	TTGTGACAGT GACCAGGCTA GACCGCCTGG CCCGCAGCAC
	CCGCGACCTA

5351	CTGGACATTG CCGAGCGCAT CCAGGAGGCC GGCGCGGGCC
	TGCGTAGCCT

5401	GGCAGAGCCG TGGGCCGACA CCACCACGCC GGCCGGCCGC
	ATGGTGTTGA

5451	CCGTGTTCGC CGGCATTGCC GATTACGACC GTTCCCTAAT
	CATCGACCGC

5501	ACCCGGAGCG GGCGCGAGGC CGCCAAGGCC CGAGGCGTGA
	AGTTTGGCCC

5551	CCGCCCTACC CTCACCCCGG CACAGATCGC GCACGCCCGC
	GAGCTGATCG

5601	ACCAGGAAGG CCGCACCGTG AAAGAGGCGG CTGCACTGCT
	TGGCGTGCAT

5651	CGCTCGACCC TGTACCGCGC ACTTGAGCGC AGCGAGGAAG
	TGACGCCCAC

5701	CGAGGCCAGG CGGCGCGGTG CCTTCCGTGA GGACGCATTG
	ACCGAGGCCG

5751	ACGCCCTGGC GGCCGCCGAG AATGAACGCC AAGAGGAACA
	AGCATGAAAC

5801	CGCACCAGGA CGGCCAGGAC GAACCGTTTT TCATTACCGA
	AGAGATCGAG

5851	GCGGAGATGA TCGCGGCCGG GTACGTGTTC GAGCCGCCCG
	CGCACGTCTC

5901	AACCGTGCGG CTGCATGAAA TCCTGGCCGG TTTGTCTGAT
	GCCAAGCTGG

5951	CGGCCTGGCC GGCCAGCTTG GCCGCTGAAG AAACCGAGCG
	CCGCCGTCTA

6001	AAAAGGTGAT GTGTATTTGA GTAAAACAGC TTGCGTCATG
	CGGTCGCTGC

6051	GTATATGATG CGATGAGTAA ATAAACAAAT ACGCAAGGGG
	AACGCATGAA

6101	GGTTATCGCT GTACTTAACC AGAAAGGCGG GTCAGGCAAG
	ACGACCATCG

6151	CAACCCATCT AGCCCGCGCC CTGCAACTCG CCGGGGCCGA
	TGTTCTGTTA

6201	GTCGATTCCG ATCCCCAGGG CAGTGCCCGC GATTGGGCGG
	CCGTGCGGGA

6251	AGATCAACCG CTAACCGTTG TCGGCATCGA CCGCCCGACG
	ATTGACCGCG

6301	ACGCCAAGGC CATCGGCCGG CGCGACTTCG TAGTGATCGA
	CGGAGCGCCC

6351	CAGGCGGCGG ACTTGGCTGT GTCCGCGATC AAGGCAGCCG
	ACTTCGTGCT

6401	GATTCCGGTG CAGCCAAGCC CTTACGACAT ATGGGCCACC
	GCCGACCTGG

6451	TGGAGCTGGT TAAGCAGCGC ATTGAGGTCA CGGATGGAAG
	GCTACAAGCG

6501	GCCTTTGTCG TGTCGCGGGC GATCAAAGGC ACGCGCATCG
	GCGGTGAGGT

6551	TGCCGAGGCG CTGGCCGGGT ACGAGCTGCC CATTCTTGAG
	TCCCGTATCA

6601	CGCAGCGCGT GAGCTACCCA GGCACTGCCG CCGCCGGCAC
	AACCGTTCTT

6651	GAATCAGAAC CCGAGGGCGA CGCTGCCCGC GAGGTCCAGG
	CGCTGGCCGC

6701	TGAAATTAAA TCAAAACTCA TTTGAGTTAA TGAGGTAAAG
	AGAAAATGAG

6751	CAAAAGCACA AACACGCTAA GTGCCGGCCG TCCGAGCGCA
	CGCAGCAGCA

6801	AGGCTGCAAC GTTGGCCAGC CTGGCAGACA CGCCAGCCAT
	GAAGCGGGTC

6851	AACTTTCAGT TGCCGGCGGA GGATCACACC AAGCTGAAGA
	TGTACGCGGT

6901	ACGCCAAGGC AAGACCATTA CCGAGCTGCT ATCTGAATAC
	ATCGCGCAGC

6951	TACCAGAGTA AATGAGCAAA TGAATAAATG AGTAGATGAA
	TTTTAGCGGC

7001	TAAAGGAGGC GGCATGGAAA ATCAAGAACA ACCAGGCACC
	GACGCCGTGG

7051	AATGCCCCAT GTGTGGAGGA ACGGGCGGTT GGCCAGGCGT
	AAGCGGCTGG

7101	GTTGTCTGCC GGCCCTGCAA TGGCACTGGA ACCCCCAAGC
	CCGAGGAATC

7151	GGCGTGACGG TCGCAAACCA TCCGGCCCGG TACAAATCGG
	CGCGGCGCTG

7201	GGTGATGACC TGGTGGAGAA GTTGAAGGCC GCGCAGGCCG
	CCCAGCGGCA

7251	ACGCATCGAG GCAGAAGCAC GCCCCGGTGA ATCGTGGCAA
	GCGGCCGCTG

7301	ATCGAATCCG CAAAGAATCC CGGCAACCGC CGGCAGCCGG
	TGCGCCGTCG

7351	ATTAGGAAGC CGCCCAAGGG CGACGAGCAA CCAGATTTTT
	TCGTTCCGAT

7401	GCTCTATGAC GTGGGCACCC GCGATAGTCG CAGCATCATG
	GACGTGGCCG

7451	TTTTCCGTCT GTCGAAGCGT GACCGACGAG CTGGCGAGGT
	GATCCGCTAC

7501	GAGCTTCCAG ACGGGCACGT AGAGGTTTCC GCAGGGCCGG
	CCGGCATGGC

7551	CAGTGTGTGG GATTACGACC TGGTACTGAT GGCGGTTTCC
	CATCTAACCG

7601	AATCCATGAA CCGATACCGG GAAGGGAAGG GAGACAAGCC
	CGGCCGCGTG

7651	TTCCGTCCAC ACGTTGCGGA CGTACTCAAG TTCTGCCGGC
	GAGCCGATGG

7701	CGGAAAGCAG AAAGACGACC TGGTAGAAAC CTGCATTCGG
	TTAAACACCA

7751	CGCACGTTGC CATGCAGCGT ACGAAGAAGG CCAAGAACGG
	CCGCCTGGTG

7801	ACGGTATCCG AGGGTGAAGC CTTGATTAGC CGCTACAAGA
	TCGTAAAGAG

7851	CGAAACCGGG CGGCCGGAGT ACATCGAGAT CGAGCTAGCT
	GATTGGATGT

7901	ACCGCGAGAT CACAGAAGGC AAGAACCCGG ACGTGCTGAC
	GGTTCACCCC

7951	GATTACTTTT TGATCGATCC CGGCATCGGC CGTTTTCTCT
	ACCGCCTGGC

8001	ACGCCGCGCC GCAGGCAAGG CAGAAGCCAG ATGGTTGTTC
	AAGACGATCT

8051	ACGAACGCAG TGGCAGCGCC GGAGAGTTCA AGAAGTTCTG
	TTTCACCGTG

8101	CGCAAGCTGA TCGGGTCAAA TGACCTGCCG GAGTACGATT
	TGAAGGAGGA

8151	GGCGGGGCAG GCTGGCCCGA TCCTAGTCAT GCGCTACCGC
	AACCTGATCG

8201	AGGGCGAAGC ATCCGCCGGT TCCTAATGTA CGGAGCAGAT
	GCTAGGGCAA

8251	ATTGCCCTAG CAGGGGAAAA AGGTCGAAAA GGTCTCTTTC
	CTGTGGATAG

8301	CACGTACATT GGGAACCCAA AGCCGTACAT TGGGAACCGG
	AACCCGTACA

8351	TTGGGAACCC AAAGCCGTAC ATTGGGAACC GGTCACACAT
	GTAAGTGACT

8401	GATATAAAAG AGAAAAAAGG CGATTTTTCC GCCTAAAACT
	CTTTAAAACT

8451	TATTAAAACT CTTAAAACCC GCCTGGCCTG TGCATAACTG
	TCTGGCCAGC

8501	GCACAGCCGA AGAGCTGCAA AAAGCGCCTA CCCTTCGGTC
	GCTGCGCTCC

8551	CTACGCCCCG CCGCTTCGCG TCGGCCTATC GCGGCCGCTG
	GCCGCTCAAA

8601	AATGGCTGGC CTACGGCCAG GCAATCTACC AGGGCGCGGA
	CAAGCCGCGC

8651	CGTCGCCACT CGACCGCCGG CGCCCACATC AAGGCACCCT
	GCCTCGCGCG

8701	TTTCGGTGAT GACGGTGAAA ACCTCTGACA CATGCAGCTC
	CCGGAGACGG

8751	TCACAGCTTG TCTGTAAGCG GATGCCGGGA GCAGACAAGC
	CCGTCAGGGC

8801	GCGTCAGCGG GTGTTGGCGG GTGTCGGGGC GCAGCCATGA
	CCCAGTCACG

8851	TAGCGATAGC GGAGTGTATA CTGGCTTAAC TATGCGGCAT
	CAGAGCAGAT

8901	TGTACTGAGA GTGCACCATA TGCGGTGTGA AATACCGCAC
	AGATGCGTAA

8951	GGAGAAAATA CCGCATCAGG CGCTCTTCCG CTTCCTCGCT
	CACTGACTCG

9001	CTGCGCTCGG TCGTTCGGCT GCGGCGAGCG GTATCAGCTC
	ACTCAAAGGC

9051	GGTAATACGG TTATCCACAG AATCAGGGGA TAACGCAGGA
	AAGAACATGT

9101	GAGCAAAAGG CCAGCAAAAG GCCAGGAACC GTAAAAAGGC
	CGCGTTGCTG

9151	GCGTTTTTCC ATAGGCTCCG CCCCCCTGAC GAGCATCACA
	AAAATCGACG

9201	CTCAAGTCAG AGGTGGCGAA ACCCGACAGG ACTATAAAGA
	TACCAGGCGT

9251	TTCCCCCTGG AAGCTCCCTC GTGCGCTCTC CTGTTCCGAC
	CCTGCCGCTT

9301	ACCGGATACC TGTCCGCCTT TCTCCCTTCG GGAAGCGTGG
	CGCTTTCTCA

9351	TAGCTCACGC TGTAGGTATC TCAGTTCGGT GTAGGTCGTT
	CGCTCCAAGC

9401	TGGGCTGTGT GCACGAACCC CCCGTTCAGC CCGACCGCTG
	CGCCTTATCC

9451	GGTAACTATC GTCTTGAGTC CAACCCGGTA AGACACGACT
	TATCGCCACT

9501	GGCAGCAGCC ACTGGTAACA GGATTAGCAG AGCGAGGTAT
	GTAGGCGGTG

9551	CTACAGAGTT CTTGAAGTGG TGGCCTAACT ACGGCTACAC
	TAGAAGGACA

9601	GTATTTGGTA TCTGCGCTCT GCTGAAGCCA GTTACCTTCG
	GAAAAAGAGT

9651	TGGTAGCTCT TGATCCGGCA AACAAACCAC CGCTGGTAGC
	GGTGGTTTTT

9701	TTGTTTGCAA GCAGCAGATT ACGCGCAGAA AAAAAGGATC
	TCAAGAAGAT

9751	CCTTTGATCT TTTCTACGGG GTCTGACGCT CAGTGGAACG
	AAAACTCACG

9801	TTAAGGGATT TTGGTCATGC ATTCTAGGTA CTAAAACAAT
	TCATCCAGTA

9851	AAATATAATA TTTTATTTTC TCCCAATCAG GCTTGATCCC
	CAGTAAGTCA

9901	AAAAATAGCT CGACATACTG TTCTTCCCCG ATATCCTCCC
	TGATCGACCG

9951	GACGCAGAAG GCAATGTCAT ACCACTTGTC CGCCCTGCCG
	CTTCTCCCAA

10001	GATCAATAAA GCCACTTACT TTGCCATCTT TCACAAAGAT
	GTTGCTGTCT

10051	CCCAGGTCGC CGTGGGAAAA GACAAGTTCC TCTTCGGGCT
	TTTCCGTCTT

10101	TAAAAAATCA TACAGCTCGC GCGGATCTTT AAATGGAGTG
	TCTTCTTCCC

10151	AGTTTTCGCA ATCCACATCG GCCAGATCGT TATTCAGTAA
	GTAATCCAAT

10201	TCGGCTAAGC GGCTGTCTAA GCTATTCGTA TAGGGACAAT
	CCGATATGTC

10251	GATGGAGTGA AAGAGCCTGA TGCACTCCGC ATACAGCTCG
	ATAATCTTTT

10301	CAGGGCTTTG TTCATCTTCA TACTCTTCCG AGCAAAGGAC
	GCCATCGGCC

10351	TCACTCATGA GCAGATTGCT CCAGCCATCA TGCCGTTCAA
	AGTGCAGGAC

10401	CTTTGGAACA GGCAGCTTTC CTTCCAGCCA TAGCATCATG
	TCCTTTTCCC

10451	GTTCCACATC ATAGGTGGTC CCTTTATACC GGCTGTCCGT
	CATTTTTAAA

10501	TATAGGTTTT CATTTTCTCC CACCAGCTTA TATACCTTAG
	CAGGAGACAT

10551	TCCTTCCGTA TCTTTTACGC AGCGGTATTT TTCGATCAGT
	TTTTTCAATT

10601	CCGGTGATAT TCTCATTTTA GCCATTTATT ATTTCCTTCC
	TCTTTTCTAC

10651	AGTATTTAAA GATACCCCAA GAAGCTAATT ATAACAAGAC
	GAACTCCAAT

10701	TCACTGTTCC TTGCATTCTA AAACCTTAAA TACCAGAAAA
	CAGCTTTTTC

10751	AAAGTTGTTT TCAAAGTTGG CGTATAACAT AGTATCGACG
	GAGCCGATTT

10801	TGAAACCGCG GTGATCACAG GCAGCAACGC TCTGTCATCG
	TTACAATCAA

10851	CATGCTACCC TCCGCGAGAT CATCCGTGTT TCAAACCCGG
	CAGCTTAGTT

10901	GCCGTTCTTC CGAATAGCAT CGGTAACATG AGCAAAGTCT
	GCCGCCTTAC

10951	AACGGCTCTC CCGCTGACGC CGTCCCGGAC TGATGGGCTG
	CCTGTATCGA

11001	GTGGTGATTT TGTGCCGAGC TGCCGGTCGG GGAGCTGTTG
	GCTGGCTGGT

11051	GGCAGGATAT ATTGTGGTGT AAACAAATTG ACGCTTAGAC
	AACTTAATAA

11101	CACATTGCGG ACGTTTTTAA TGTACTGAAT TAACGCCGAA
	TTAATTCCTA

11151	GGCCACCATG TTGGGCCCGG GGCGCGCCGT ACGTAGTGTT
	TATCTTTGTT

11201	GCTTTTCTGA ACAATTTATT TACTATGTAA ATATATTATC
	AATGTTTAAT

11251	CTATTTTAAT TTGCACATGA ATTTTCATTT TATTTTTACT
	TTACAAAACA

11301	AATAAATATA TATGCAAAAA AATTTACAAA CGATGCACGG
	GTTACAAACT

11351	AATTTCATTA AATGCTAATG CAGATTTTGT GAAGTAAAAC
	TCCAATTATG

11401	ATGAAAAATA CCACCAACAC CACCTGCGAA ACTGTATCCC
	AACTGTCCTT

11451	AATAAAAATG TTAAAAAGTA TATTATTCTC ATTTGTCTGT
	CATAATTTAT

11501	GTACCCCACT TTAATTTTTC TGATGTACTA AACCGAGGGC
	AAACTGAAAC

11551	CTGTTCCTCA TGCAAAGCCC CTACTCACCA TGTATCATGT
	ACGTGTCATC

11601	ACCCAACAAC TCCACTTTTG CTATATAACA ACACCCCCGT
	CACACTCTCC

11651	CTCTCTAACA CACACCCCAC TAACAATTCC TTCACTTGCA
	GCACTGTTGC

11701	ATCATCATCT TCATTGCAAA ACCCTAAACT TCACCTTCAA
	CCGCGGCCGC

11751	ATGGCTTCTA TGATATCCTC TTCCGCTGTG ACAACAGTCA
	GCCGTGCCTC

11801	TAGGGGGCAA TCCGCCGCAG TGGCTCCATT CGGCGGCCTC
	AAATCCATGA

11851	CTGGATTCCC AGTGAAGAAG GTCAACACTG ACATTACTTC
	CATTACAAGC

11901	AATGGTGGAA GAGTAAAGTG CATGCAGGTG TGGCCTCCAA
	TTGGAAAGAA

11951	GAAGTTTGAG ACTCTTTCCT ATTTGCCACC ATTGACGAGA
	GATTCTAGAG

12001	TGAGTAACAA GAACAACGAT GAGCTGCAGT GGCAATCCTG
	GTTCAGCAAG

12051	GCGCCCACCA CCGAGGCGAA CCCGATGGCC ACCATGTTGC
	AGGATATCGG

12101	CGTTGCGCTC AAACCGGAAG CGATGGAGCA GCTGAAAAAC
	GATTATCTGC

12151	GTGACTTCAC CGCGTTGTGG CAGGATTTTT TGGCTGGCAA
	GGCGCCAGCC

12201	GTCAGCGACC GCCGCTTCAG CTCGGCAGCC TGGCAGGGCA
	ATCCGATGTC

12251	GGCCTTCAAT GCCGCATCTT ACCTGCTCAA CGCCAAATTC
	CTCAGTGCCA

12301	TGGTGGAGGC GGTGGACACC GCACCCCAGC AAAAGCAGAA
	AATACGCTTT

12351	GCCGTGCAGC AGGTGATTGA TGCCATGTCG CCCGCGAACT
	TCCTCGCCAC

12401	CAACCCGGAA GCGCAGCAAA AACTGATTGA AACCAAGGGC
	GAGAGCCTGA

12451	CGCGTGGCCT GGTCAATATG CTGGGCGATA TCAACAAGGG
	CCATATCTCG

12501	CTGTCGGACG AATCGGCCTT TGAAGTGGGC CGCAACCTGG
	CCATTACCCC

12551	GGGCACCGTG ATTTACGAAA ATCCGCTGTT CCAGCTGATC
	CAGTACACGC

12601	CGACCACGCC GACGGTCAGC CAGCGCCCGC TGTTGATGGT
	GCCGCCGTGC

12651	ATCAACAAGT TCTACATCCT CGACCTGCAA CCGGAAAATT
	CGCTGGTGCG

12701	CTACGCGGTG GAGCAGGGCA ACACCGTGTT CCTGATCTCG
	TGGAGCAATC

12751	CGGACAAGTC GCTGGCCGGC ACCACCTGGG ACGACTACGT
	GGAGCAGGGC

12801	GTGATCGAAG CGATCCGCAT CGTCCAGGAC GTCAGCGGCC
	AGGACAAGCT

12851	GAACATGTTC GGCTTCTGCG TGGGCGGCAC CATCGTTGCC
	ACCGCACTGG

12901	CGGTACTGGC GGCGCGTGGC CAGCACCCGG CGGCCAGCCT
	GACCCTGCTG

12951	ACCACCTTCC TCGACTTCAG CGACACCGGC GTGCTCGACG
	TCTTCGTCGA

13001	TGAAACCCAG GTCGCGCTGC GTGAACAGCA ATTGCGCGAT
	GGCGGCCTGA

13051	TGCCGGGCCG TGACCTGGCC TCGACCTTCT CGAGCCTGCG
	TCCGAACGAC

13101	CTGGTATGGA ACTATGTGCA GTCGAACTAC CTCAAAGGCA
	ATGAGCCGGC

13151	GGCGTTTGAC CTGCTGTTCT GGAATTCGGA CAGCACCAAT
	TTGCCGGGCC

13201	CGATGTTCTG CTGGTACCTG CGCAACACCT ACCTGGAAAA
	CAGCCTGAAA

13251	GTGCCGGGCA AGCTGACGGT GGCCGGCGAA AAGATCGACC
	TCGGCCTGAT

13301	CGACGCCCCG GCCTTCATCT ACGGTTCGCG CGAAGACCAC
	ATCGTGCCGT

13351	GGATGTCGGC GTACGGTTCG CTCGACATCC TCAACCAGGG
	CAAGCCGGGC

13401	GCCAACCGCT TCGTGCTGGG CGCGTCCGGC CATATCGCCG
	GCGTGATCAA

13451	CTCGGTGGCC AAGAACAAGC GCAGCTACTG GATCAACGAC
	GGTGGCGCCG

13501	CCGATGCCCA GGCCTGGTTC GATGGCGCGC AGGAAGTGCC
	GGGCAGCTGG

13551	TGGCCGCAAT GGGCCGGGTT CCTGACCCAG CATGGCGGCA
	AGAAGGTCAA

13601	GCCCAAGGCC AAGCCCGGCA ACGCCCGCTA CACCGCGATC
	GAGGCGGCGC

13651	CCGGCCGTTA CGTCAAAGCC AAGGGCTGAG CGGCCGCTGA
	GTAATTCTGA

13701	TATTAGAGGG AGCATTAATG TGTTGTTGTG ATGTGGTTTA
	TATGGGGAAA

13751	TTAAATAAAT GATGTATGTA CCTCTTGCCT ATGTAGGTTT
	GTGTGTTTTG

13801	TTTTGTTGTC TAGCTTTGGT TATTAAGTAG TAGGGACGTT
	CGTTCGTGTC

13851	TCAAAAAAAG GGGTACTACC ACTCTGTAGT GTATATGGAT
	GCTGGAAATC

13901	AATGTGTTTT GTATTTGTTC ACCTCCATTG TTGAATTCAA
	TGTCAAATGT

13951	GTTTTGCGTT GGTTATGTGT AAAATTACTA TCTTTCTCGT
	CCGATGATCA

14001	AAGTTTTAAG CAACAAAACC AAGGGTGAAA TTTAAACTGT
	GCTTTGTTGA

14051	AGATTCTTTT ATCATATTGA AAATCAAATT ACTAGCAGCA
	GATTTTACCT

14101	AGCATGAAAT TTTATCAACA GTACAGCACT CACTAACCAA
	GTTCCAAACT

14151	AAGATGCGCC ATTAACATCA GCCAATAGGC ATTTTCAGCA
	AGGCGCGCCC

14201	GCGCCGATGT ATGTGACAAC CCTCGGGATT GTTGATTTAT
	TTCAAAACTA

14251	AGAGTTTTTG TCTTATTGTT CTCGTCTATT TTGGATATCA
	ATCTTAGTTT

14301	TATATCTTTT CTAGTTCTCT ACGTGTTAAA TGTTCAACAC
	ACTAGCAATT

14351	TGGCCTGCCA GCGTATGGAT TATGGAACTA TCAAGTCTGT
	GACGCGCCGT

14401	ACGTAGTGTT TATCTTTGTT GCTTTTCTGA ACAATTTATT
	TACTATGTAA

14451	ATATATTATC AATGTTTAAT CTATTTTAAT TTGCACATGA
	ATTTTCATTT

14501	TATTTTTACT TTACAAAACA AATAAATATA TATGCAAAAA
	AATTTACAAA

14551	CGATGCACGG GTTACAAACT AATTTCATTA AATGCTAATG
	CAGATTTTGT

14601	GAAGTAAAAC TCCAATTATG ATGAAAAATA CCACCAACAC
	CACCTGCGAA

14651	ACTGTATCCC AACTGTCCTT AATAAAAATG TTAAAAAGTA
	TATTATTCTC

14701	ATTTGTCTGT CATAATTTAT GTACCCCACT TTAATTTTTC
	TGATGTACTA

14751	AACCGAGGGC AAACTGAAAC CTGTTCCTCA TGCAAAGCCC
	CTACTCACCA

14801	TGTATCATGT ACGTGTCATC ACCCAACAAC TCCACTTTTG
	CTATATAACA

14851	ACACCCCCGT CACACTCTCC CTCTCTAACA CACACCCCAC
	TAACAATTCC

14901	TTCACTTGCA GCACTGTTGC ATCATCATCT TCATTGCAAA
	ACCCTAAACT

14951	TCACCTTCAA CCGCGGCCGC ATGGCTTCTA TGATATCCTC
	TTCCGCTGTG

15001	ACAACAGTCA GCCGTGCCTC TAGGGGGCAA TCCGCCGCAG
	TGGCTCCATT

15051	CGGCGGCCTC AAATCCATGA CTGGATTCCC AGTGAAGAAG
	GTCAACACTG

15101	ACATTACTTC CATTACAAGC AATGGTGGAA GAGTAAAGTG
	CATGCAGGTG

15151	TGGCCTCCAA TTGGAAAGAA GAAGTTTGAG ACTCTTTCCT
	ATTTGCCACC

15201	ATTGACGAGA GATTCTAGAG TGACTCAGCG CATTGCGTAT
	GTGACCGGCG

15251	GCATGGGTGG TATCGGAACC GCCATTTGCC AGCGGCTGGC
	CAAGGATGGC

15301	TTTCGTGTGG TGGCCGGTTG CGGCCCCAAC TCGCCGCGCC
	GCGAAAAGTG

15351	GCTGGAGCAG CAGAAGGCCC TGGGCTTCGA TTTCATTGCC
	TCGGAAGGCA

15401	ATGTGGCTGA CTGGGACTCG ACCAAGACCG CATTCGACAA
	GGTCAAGTCC

15451	GAGGTCGGCG AGGTTGATGT GCTGATCAAC AACGCCGGTA
	TCACCCGCGA

15501	CGTGGTGTTC CGCAAGATGA CCCGCGCCGA CTGGGATGCG
	GTGATCGACA

15551	CCAACCTGAC CTCGCTGTTC AACGTCACCA AGCAGGTGAT
	CGACGGCATG

15601	GCCGACCGTG GCTGGGGCCG CATCGTCAAC ATCTCGTCGG
	TGAACGGGCA

15651	GAAGGGCCAG TTCGGCCAGA CCAACTACTC CACCGCCAAG
	GCCGGCCTGC

15701	ATGGCTTCAC CATGGCACTG GCGCAGGAAG TGGCGACCAA
	GGGCGTGACC

15751	GTCAACACGG TCTCTCCGGG CTATATCGCC ACCGACATGG
	TCAAGGCGAT

15801	CCGCCAGGAC GTGCTCGACA AGATCGTCGC GACGATCCCG
	GTCAAGCGCC

15851	TGGGCCTGCC GGAAGAGATC GCCTCGATCT GCGCCTGGTT
	GTCGTCGGAG

15901	GAGTCCGGTT TCTCGACCGG CGCCGACTTC TCGCTCAACG
	GCGGCCTGCA

15951	TATGGGCTGA GCGGCCGCTG AGTAATTCTG ATATTAGAGG
	GAGCATTAAT

16001	GTGTTGTTGT GATGTGGTTT ATATGGGGAA ATTAAATAAA
	TGATGTATGT

16051	ACCTCTTGCC TATGTAGGTT TGTGTGTTTT GTTTTGTTGT
	CTAGCTTTGG

16101	TTATTAAGTA GTAGGGACGT TCGTTCGTGT CTCAAAAAAA
	GGGGTACTAC

16151	CACTCTGTAG TGTATATGGA TGCTGGAAAT CAATGTGTTT
	TGTATTTGTT

16201	CACCTCCATT GTTGAATTCA ATGTCAAATG TGTTTTGCGT
	TGGTTATGTG

16251	TAAAATTACT ATCTTTCTCG TCCGATGATC AAAGTTTTAA
	GCAACAAAAC

16301	CAAGGGTGAA ATTTAAACTG TGCTTTGTTG AAGATTCTTT
	TATCATATTG

16351	AAAATCAAAT TACTAGCAGC AGATTTTACC TAGCATGAAA
	TTTTATCAAC

16401	AGTACAGCAC TCACTAACCA AGTTCCAAAC TAAGATGCGC
	CATTAACATC

16451	AGCCAATAGG CATTTTCAGC AAGGCGCGTA AGGGGATCCG
	TACGTAAGTA

16501	CGTACTCAAA ATGCCAACAA ATAAAAAAAA AGTTGCTTTA
	ATAATGCCAA

16551	AACAAATTAA TAAAACACTT ACAACACCGG ATTTTTTTTA
	ATTAAAATGT

16601	GCCATTTAGG ATAAATAGTT ATTTTTTTTA ATAATTATTT
	AAAAAGCCGT

16651	ATCTACTAAA ATGATTTTTA TTTGGTTGAA AATATTAATA
	TGTTTAAATC

16701	AACACAATCT ATCAAAATTA AACTAAAAAA AAAATAAGTG
	TACGTGGTTA

16751	ACATTAGTAC AGTAATATAA GAGGAAAATG AGAAATTAAG
	AAATTGAAAG

16801	CGAGTCTAAT TTTTAAATTA TGAACCTGCA TATATAAAAG
	GAAAGAAAGA

16851	ATCCAGGAAG AAAAGAAATG AAACCATGCA TGGTCCCCTC
	GTCATCACGA

16901	GTTTCTGCCA TTTGCAATAG AAACACTGAA ACACCTTTCT
	CTTTGTCACT

16951	TAATTGAGAT GCCGAAGCCA CCTCACACCA TGAACTTCAT
	GAGGTGTAGC

17001	ACCCAAGGCT TCCATAGCCA TGCATACTGA AGAATGTCTC
	AAGCTCAGCA

17051	CCCTACTTCT GTGACGTGTC CCTCATTCAC CTTCCTCTCT
	TCCCTATAAA

17101	TAACCACGCC TCAGGTTCTC CGCTTCACAA CTCAAACATT
	CTCTCCATTG

17151	GTCCTTAAAC ACTCATCAGT CATCACCGCG GCCGCGGAAT
	TCATGGCTTC

17201	TATGATATCC TCTTCCGCTG TGACAACAGT CAGCCGTGCC
	TCTAGGGGGC

17251	AATCCGCCGC AGTGGCTCCA TTCGGCGGCC TCAAATCCAT
	GACTGGATTC

17301	CCAGTGAAGA AGGTCAACAC TGACATTACT TCCATTACAA
	GCAATGGTGG

17351	AAGAGTAAAG TGCATGCAGG TGTGGCCTCC AATTGGAAAG
	AAGAAGTTTG

17401	AGACTCTTTC CTATTTGCCA CCATTGACGA GAGATTCTAG
	AGTGACTGAC

17451	GTTGTCATCG TATCCGCCGC CCGCACCGCG GTCGGCAAGT
	TTGGCGGCTC

17501	GCTGGCCAAG ATCCCGGCAC CGGAACTGGG TGCCGTGGTC
	ATCAAGGCCG

17551	CGCTGGAGCG CGCCGGCGTC AAGCCGGAGC AGGTGAGCGA
	AGTCATCATG

17601	GGCCAGGTGC TGACCGCCGG TTCGGGCCAG AACCCCGCAC
	GCCAGGCCGC

17651	GATCAAGGCC GGCCTGCCGG CGATGGTGCC GGCCATGACC
	ATCAACAAGG

17701	TGTGCGGCTC GGGCCTGAAG GCCGTGATGC TGGCCGCCAA
	CGCGATCATG

17751	GCGGGCGACG CCGAGATCGT GGTGGCCGGC GGCCAGGAAA
	ACATGAGCGC

17801	CGCCCCGCAC GTGCTGCCGG GCTCGCGCGA TGGTTTCCGC
	ATGGGCGATG

17851	CCAAGCTGGT CGACACCATG ATCGTCGACG GCCTGTGGGA
	CGTGTACAAC

17901	CAGTACCACA TGGGCATCAC CGCCGAGAAC GTGGCCAAGG
	AATACGGCAT

17951	CACACGCGAG GCGCAGGATG AGTTCGCCGT CGGCTCGCAG
	AACAAGGCCG

18001	AAGCCGCGCA GAAGGCCGGC AAGTTTGACG AAGAGATCGT
	CCCGGTGCTG

18051	ATCCCGCAGC GCAAGGGCGA CCCGGTGGCC TTCAAGACCG
	ACGAGTTCGT

18101	GCGCCAGGGC GCCACGCTGG ACAGCATGTC CGGCCTCAAG
	CCCGCCTTCG

18151	ACAAGGCCGG CACGGTGACC GCGGCCAACG CCTCGGGCCT
	GAACGACGGC

18201	GCCGCCGCGG TGGTGGTGAT GTCGGCGGCC AAGGCCAAGG
	AACTGGGCCT

18251	GACCCCGCTG GCCACGATCA AGAGCTATGC CAACGCCGGT
	GTCGATCCCA

18301	AGGTGATGGG CATGGGCCCG GTGCCGGCCT CCAAGCGCGC
	CCTGTCGCGC

18351	GCCGAGTGGA CCCCGCAAGA CCTGGACCTG ATGGAGATCA
	ACGAGGCCTT

18401	TGCCGCGCAG GCGCTGGCGG TGCACCAGCA GATGGGCTGG
	GACACCTCCA

18451	AGGTCAATGT GAACGGCGGC GCCATCGCCA TCGGCCACCC
	GATCGGCGCG

18501	TCGGGCTGCC GTATCCTGGT GACGCTGCTG CACGAGATGA
	AGCGCCGTGA

18551	CGCGAAGAAG GGCCTGGCCT CGCTGTGCAT CGGCGGCGGC
	ATGGGCGTGG

18601	CGCTGGCAGT CGAGCGCAAA TAACTCGAGG CGGCCGCAGC
	CCTTTTTGTA

18651	TGTGCTACCC CACTTTTGTC TTTTTGGCAA TAGTGCTAGC
	AACCAATAAA

18701	TAATAATAAT AATAATGAAT AAGAAAACAA AGGCTTTAGC
	TTGCCTTTTG

18751	TTCACTGTAA AATAATAATG TAAGTACTCT CTATAATGAG
	TCACGAAACT

18801	TTTGCGGGAA TAAAAGGAGA AATTCCAATG AGTTTTCTGT
	CAAATCTTCT

18851	TTTGTCTCTC TCTCTCTCTC TTTTTTTTTT TTCTTTCTTC
	TGAGCTTCTT

18901	GCAAAACAAA AGGCAAACAA TAACGATTGG TCCAATGATA
	GTTAGCTTGA

18951	TCGATGATAT CTTTAGGAAG TGTTGGCAGG ACAGGACATG
	ATGTAGAAGA

19001	CTAAAATTGA AAGTATTGCA GACCCAATAG TTGAAGATTA
	ACTTTAAGAA

19051	TGAAGACGTC TTATCAGGTT CTTCATGACT TAAGCTTTAA
	GAGGAGTCCA

19101	CCATGGTAGA TCTGACTAGT GATCCGTACG TAAGTACGTA
	CTCAAAATGC

19151	CAACAAATAA AAAAAAAGTT GCTTTAATAA TGCCAAAACA
	AATTAATAAA

19201	ACACTTACAA CACCGGATTT TTTTTAATTA AAATGTGCCA
	TTTAGGATAA

19251	ATAGTTAATA TTTTTAATAA TTATTTAAAA AGCCGTATCT
	ACTAAAATGA

19301	TTTTTATTTG GTTGAAAATA TTAATATGTT TAAATCAACA
	CAATCTATCA

19351	AAATTAAACT AAAAAAAAAA TAAGTGTACG TGGTTAACAT
	TAGTACAGTA

19401	ATATAAGAGG AAAATGAGAA ATTAAGAAAT TGAAAGCGAG
	TCTAATTTTT

19451	AAATTATGAA CCTGCATATA TAAAAGGAAA GAAAGAATCC
	AGGAAGAAAA

19501	GAAATGAAAC CATGCATGGT CCCCTCGTCA TCACGAGTTT
	CTGCCATTTG

19551	CAATAGAAAC ACTGAAACAC CTTTCTCTTT GTCACTTAAT
	TGAGATGCCG

19601	AAGCCACCTC ACACCATGAA CTTCATGAGG TGTAGCACCC
	AAGGCTTCCA

19651	TAGCCATGCA TACTGAAGAA TGTCTCAAGC TCAGCACCCT
	ACTTCTGTGA

19701	CGTGTCCCTC ATTCACCTTC CTCTCTTCCC TATAAATAAC
	CACGCCTCAG

19751	GTTCTCCGCT TCACAACTCA AACATTCTCT CCATTGGTCC
	TTAAACACTC

19801	ATCAGTCATC ACCATGGACT CCAAAGAATC ATTAACTCCT
	GGTAGAGAAG

19851	AAAACCCCAG CAGTGTGCTT GCTCAGGAGA GGGGAGATGT
	GATGGACTTC

19901	TATAAAACCC TAAGAGGAGG AGCTACTGTG AAGGTTTCTG
	CGTCTTCACC

19951	CTCACTGGCT GTCGCTTCTC AATCAGACTC CAAGCAGCGA
	AGACTTTTGG

20001	TTGATTTTCC AAAAGGCTCA GTAAGCAATG CGCAGCAGCC
	AGATCTGTCC

20051	AAAGCAGTTT CACTCTCAAT GGGACTGTAT ATGGGAGAGA
	CAGAAACAAA

20101	AGTGATGGGA AATGACCTGG GATTCCCACA GCAGGGCCAA
	ATCAGCCTTT

20151	CCTCGGGGGA AACAGACTTA AAGCTTTTGG AAGAAAGCAT
	TGCAAACCTC

20201	AATAGGTCGA CCAGTGTTCC AGAGAACCCC AAGAGTTCAG
	CATCCACTGC

20251	TGTGTCTGCT GCCCCCACAG CTAGTTCTGC GGCCCCCCCG
	ACCGATGTCA

20301	GCCTGGGGGA CGAGCTCCAC TTAGACGGCG AGGACGTGGC
	GATGGCGCAT

20351	GCCGACGCGC TAGACGATTT CGATCTGGAC ATGTTGGGGG
	ACGGGGATTC

20401	CCCGGGTCCG GGATTTACCC CCCACGACTC CGCCCCCTAC
	GGCGCTCTGG

20451	ATATGGCCGA CTTCGAGTTT GAGCAGATGT TTACCGATGC
	CCTTGGAATT

20501	GACGAGTACG GTGGGACTAG CTCCAGCTCC TCAACAGCAA
	CAACAGGACC

20551	ACCTCCCAAA CTCTGCCTGG TGTGCTCTGA TGAAGCTTCA
	GGATGTCATT

20601	ATGGAGTCTT AACTTGTGGA AGCTGTAAAG TTTTCTTCAA
	AAGAGCAGTG

20651	GAAGGACAGC ACAATTACCT ATGTGCTGGA AGGAATGATT
	GCATCATCGA

20701	TAAAATTCGA AGAAAAAACT GCCCAGCATG CCGCTATCGA
	AAATGTCTTC

20751	AGGCTGGAAT GAACCTGGAA GCTCGAAAAA CAAAGAAAAA
	AATAAAAGGA

20801	ATTGCTCGAC AAAGGCCCGA GTGCGTGGTG CCGGAGAACC
	AGTGTGCAAT

20851	GAAACGGAAA GAGAAAAAGG CGCAGAGGGA AAAAGACAAA
	TTGCCCGTCA

20901	GTACGACGAC AGTAGACGAT CACATGCCTC CCATCATGCA
	ATGTGACCCT

20951	CCGCCCCCAG AGGCCGCTAG AATTCTGGAA TGTTTGCAGC
	ACGAGGTGGT

21001	GCCACGATTC CTGAATGAGA AGCTAATGGA ACAGAACAGA
	TTGAAGAACG

21051	TGCCCCCCCT CACTGCCAAT CAGAAGTCGT TGATCGCAAG
	GCTCGTGTGG

21101	TACCAGGAAG GCTATGAACA ACCTTCCGAG GAAGACCTGA
	AGAGGGTTAC

21151	ACAGTCGGAC GAGGACGACG AAGACTCGGA TATGCCGTTC
	CGTCAGATTA

21201	CCGAGATGAC GATTCTCACA GTGCAGCTCA TCGTAGAATT
	CGCTAAGGGC

21251	CTCCCGGGCT TCGCCAAGAT CTCGCAGTCG GACCAGATCA
	CGTTATTAAA

21301	GGCGTGCTCA AGTGAGGTGA TGATGCTCCG AGTGGCTCGG
	CGGTATGACG

21351	CGGCCACCGA CAGCGTACTG TTCGCGAACA ACCAGGCGTA
	CACTCGCGAC

21401	AACTACCGCA AGGCAGGCAT GGCGTACGTC ATCGAGGACC
	TGCTGCACTT

21451	CTGTCGGTGC ATGTACTCCA TGATGATGGA TAACGTGCAT
	TATGCGCTGC

21501	TTACAGCCAT TGTCATCTTC TCAGACCGGC CCGGGCTTGA
	GCAACCCCTG

21551	TTGGTGGAGG AGATCCAGAG ATATTACCTG AACACGCTAC
	GGGTGTACAT

21601	CCTGAACCAG AACAGCGCGT CGCCCCGCTG CGCCGTCATC
	TTCGGCAAGA

21651	TCCTGGGCAT ACTGACGGAG ATCCGCACGC TGGGCATGCA
	GAACTCCAAC

21701	ATGTGCATCT CCCTCAAGCT GAAGAACAGG AAGCTGCCGC
	CGTTCCTCGA

21751	GGAGATCTGG GACGTGGCGG ACGTGGCGAC GACGGCGACG
	CCGGTGGCGG

21801	CGGAGGCGCC GGCGCTCTAG CCCCCGCGCC GCCCGCCCGG
	CCGCGCGCAC

21851	GTCTAGCGCG CCTCAGGAGA GAACGCTCAT AGACTGGCTA
	GTTTTAGTGA

21901	AGTGCACGGA CACTGACGTC GGACGTGATC AACCTATTTA
	TAAGGACTGC

21951	GAATTTTACC ACTTAAGAGG GCACACCCGT ACCCGATTTC
	GTACGGGAAT

22001	TCCTGCAGCC CGGGGGATCC TTAATTAACT CGAGGAATTC
	ATCGATTCCG

22051	CGGGTACCGA GCTCGATCCG TCGACCTGCA GATCGTTCAA
	ACATTTGGCA

22101	ATAAAGTTTC TTAAGATTGA ATCCTGTTGC CGGTCTTGCG
	ATGATTATCA

22151	TATAATTTCT GTTGAATTAC GTTAAGCATG TAATAATTAA
	CATGTAATGC

22201	ATGACGTTAT TTATGAGATG GGTTTTTATG ATTAGAGTCC
	CGCAATTATA

22251	CATTTAATAC GCGATAGAAA ACAAAATATA GCGCGCAAAC
	TAGGATAAAT

22301	TATCGCGCGC GGTGTCATCT ATGTTACTAG ATCTGGCGCG
	CCCCTAGGTC

22351	TAGAGTCGAC TGTTTAAACG

Vector pMBXVT1

(SEQ ID NO: 7)

1	GGGGATCCGT ACGTAAGTAC GTACTCAAAA TGCCAACAAA
	TAAAAAAAAA

51	GTTGCTTTAA TAATGCCAAA ACAAATTAAT AAAACACTTA
	CAACACCGGA

101	TTTTTTTTAA TTAAAATGTG CCATTTAGGA TAAATAGTTA
	ATATTTTTAA

151	TAATTATTTA AAAAGCCGTA TCTACTAAAA TGATTTTTAT
	TTGGTTGAAA

201	ATATTAATAT GTTTAAATCA ACACAATCTA TCAAAATTAA
	ACTAAAAAAA

251	AAATAAGTGT ACGTGGTTAA CATTAGTACA GTAATATAAG
	AGGAAAATGA

301	GAAATTAAGA AATTGAAAGC GAGTCTAATT TTTAAATTAT
	GAACCTGCAT

351	ATATAAAAGG AAAGAAAGAA TCCAGGAAGA AAAGAAATGA
	AACCATGCAT

401	GGTCCCCTCG TCATCACGAG TTTCTGCCAT TTGCAATAGA
	AACACTGAAA

451	CACCTTTCTC TTTGTCACTT AATTGAGATG CCGAAGCCAC
	CTCACACCAT

501	GAACTTCATG AGGTGTAGCA CCCAAGGCTT CCATAGCCAT
	GCATACTGAA

551	GAATGTCTCA AGCTCAGCAC CCTACTTCTG TGACGTGTCC
	CTCATTCACC

601	TTCCTCTCTT CCCTATAAAT AACCACGCCT CAGGTTCTCC
	GCTTCACAAC

651	TCAAACATTC TCTCCATTGG TCCTTAAACA CTCATCAGTC
	ATCACCGCGG

701	CCGCGGAATT CATGGCTTCT ATGATATCCT CTTCCGCTGT
	GACAACAGTC

751	AGCCGTGCCT CTAGGGGGCA ATCCGCCGCA GTGGCTCCAT
	TCGGCGGCCT

801	CAAATCCATG ACTGGATTCC CAGTGAAGAA GGTCAACACT
	GACATTACTT

851	CCATTACAAG CAATGGTGGA AGAGTAAAGT GCATGCAGGT
	GTGGCCTCCA

901	ATTGGAAAGA AGAAGTTTGA GACTCTTTCC TATTTGCCAC
	CATTGACGAG

951	AGATTCTAGA GTGACTGACG TTGTCATCGT ATCCGCCGCC
	CGCACCGCGG

1001	TCGGCAAGTT TGGCGGCTCG CTGGCCAAGA TCCCGGCACC
	GGAACTGGGT

1051	GCCGTGGTCA TCAAGGCCGC GCTGGAGCGC GCCGGCGTCA
	AGCCGGAGCA

1101	GGTGAGCGAA GTCATCATGG GCCAGGTGCT GACCGCCGGT
	TCGGGCCAGA

1151	ACCCCGCACG CCAGGCCGCG ATCAAGGCCG GCCTGCCGGC
	GATGGTGCCG

1201	GCCATGACCA TCAACAAGGT GTGCGGCTCG GGCCTGAAGG
	CCGTGATGCT

1251	GGCCGCCAAC GCGATCATGG CGGGCGACGC CGAGATCGTG
	GTGGCCGGCG

1301	GCCAGGAAAA CATGAGCGCC GCCCCGCACG TGCTGCCGGG
	CTCGCGCGAT

1351	GGTTTCCGCA TGGGCGATGC CAAGCTGGTC GACACCATGA
	TCGTCGACGG

1401	CCTGTGGGAC GTGTACAACC AGTACCACAT GGGCATCACC
	GCCGAGAACG

1451	TGGCCAAGGA ATACGGCATC ACACGCGAGG CGCAGGATGA
	GTTCGCCGTC

1501	GGCTCGCAGA ACAAGGCCGA AGCCGCGCAG AAGGCCGGCA
	AGTTTGACGA

1551	AGAGATCGTC CCGGTGCTGA TCCCGCAGCG CAAGCGCGAC
	CCGGTGGCCT

1601	TCAAGACCGA CGAGTTCGTG CGCCAGGGCG CCACGCTGGA
	CAGCATGTCC

1651	GGCCTCAAGC CCGCCTTCGA CAAGGCCGGC ACGGTGACCG
	CGGCCAACGC

1701	CTCGGGCCTG AACGACGGCG CCGCCGCGGT GGTGGTGATG
	TCGGCGGCCA

1751	AGGCCAAGGA ACTGGGCCTG ACCCCGCTGG CCACGATCAA
	GAGCTATGCC

1801	AACGCCGGTG TCGATCCCAA GGTGATGGGC ATGGGCCCGG
	TGCCGGCCTC

1851	CAAGCGCGCC CTGTCGCGCG CCGAGTGGAC CCCGCAAGAC
	CTGGACCTGA

1901	TGGAGATCAA CGAGGCCTTT GCCGCGCAGG CGCTGGCGGT
	GCACCAGCAG

1951	ATGGGCTGGG ACACCTCCAA GGTCAATGTG AACGGCGGCG
	CCATCGCCAT

2001	CGGCCACCCG ATCGGCGCGT CGGGCTGCCG TATCCTGGTG
	ACGCTGCTGC

2051	ACGAGATGAA GCGCCGTGAC GCGAAGAAGG GCCTGGCCTC
	GCTGTGCATC

2101	GGCGGCGGCA TGGGCGTGGC GCTGGCAGTC GAGCGCAAAT
	AACTCGAGGC

2151	GGCCGCAGCC CTTTTTGTAT GTGCTACCCC ACTTTTGTCT
	TTTTGGCAAT

2201	AGTGCTAGCA ACCAATAAAT AATAATAATA ATAATGAATA
	AGAAAACAAA

2251	GGCTTTAGCT TGCCTTTTGT TCACTGTAAA ATAATAATGT
	AAGTACTCTC

2301	TATAATGAGT CACGAAACTT TTGCGGGAAT AAAAGGAGAA
	ATTCCAATGA

2351	GTTTTCTGTC AAATCTTCTT TTGTCTCTCT CTCTCTCTCT
	TTTTTTTTTT

2401	TCTTTCTTCT GAGCTTCTTG CAAAACAAAA GGCAAACAAT
	AACGATTGGT

2451	CCAATGATAG TTAGCTTGAT CGATGATATC TTTAGGAAGT
	GTTGGCAGGA

2501	CAGGACATGA TGTAGAAGAC TAAAATTGAA AGTATTGCAG
	ACCCAATAGT

2551	TGAAGATTAA CTTTAAGAAT GAAGACGTCT TATCAGGTTC
	TTCATGACTT

2601	AAGCTTAACT TTTGAGGCAG AGCTTGTAAA TTGTAACAGG
	TGAGGTAGAA

2651	AGACGGAAAG TACTTTTAAT AATAAAAGGT TTGAAAAATT
	AAGAAAAGAA

2701	GAAGAAAATA TTTTGTGAGT GCACGCGATG GATCTAATCC
	TTCCATGAAA

2751	AAGAATATCA AGAATAACAA AAATTGACAA AATCAGCGAA
	TACTTCACCC

2801	AAAAGTCTAC ACAATAATAA ATGCTAAATC ACATATAATT
	TGTGATGCAT

2851	AACGCATTAC GCTATCGTAA TCCTTTACAA CAAGCAAGAA
	CGTCATCCCA

2901	GAATCTCAAC TCAAATCAAA ACCGTTCATT CATAAATAAA
	AAATATTCTT

2951	ACATTCTTTT GCAAATAGAA CCTTTGCCAA ATTGAAATAA
	CAAACTCTAG

3001	GTATTTGTCA AATTAACTTA CCAACTTCTC GTTATATAAT
	TTTAGATTTA

3051	TAATCATGTC TATAAATTAT TTCTATACAC TCTCTCTCAA
	ATTTGACCTT

3101	TACATTCTGT GATTTATTTG AACAGAATAA ATCACTGTAA
	AACTAAACAA

3151	CTCTTTAAAA AAGGTAAATT AGGAAAAGTC GAAATCAATA
	AATTATAAAT

3201	CAATCCCTAG AAAACTGCAA GATAATATTC TTACCAAAAT
	CATTTAAATA

3251	AATTTGTAAG TTTTTTCTTT ATACCAATTT TCTGAGACCC
	AGAGACATTC

3301	TTAAATTCAT AACAACGGTT TTAAGTATCA GAGTATAACA
	TCTTTGTATA

3351	AATAGATTTT TGAACGTTCA ATAACTAACA CGTCAGTTTT
	TGTTTCCACG

3401	TTGTACGTTT AATAACAATA AATGCGTGAG TTAGATTACT
	AATCAGAAGT

3451	TAGAAGTGTA CAAGACTAAC TTTATACAGA AATATATTGT
	TTCAGACTGC

3501	ACTTTATGGT GCGTAGCACC TCAAAACTCT TACCTTTCGC
	ATACATTTTC

3551	ACACTTCATC CAAACCTTTC GAAAAGTCAC TTCCCTTATA
	TTAAAGGACT

3601	ATGATATAAA AAAGACTATA TGTGTTACTA ATTTATTGGT
	TTGTATATTT

3651	GTAATAAATC GTTCCATCAA GAGGAGCTAT CACATATTGA
	GAACAGTAAA

3701	AAAAAAAAAA AGTTGGTAAA AAAACATTTT CTTATATTAT
	ATCATAAAAT

3751	CAGTTACCAT AGTATTTTAG AGTTTTCAGA ATAATGCTTC
	ACCCAACTTG

3801	CAACTCATTG TGCCTCAAAA CAGGACGTAA CCATGTTACT
	CACTCTCCTG

3851	CACAACCCCT TGTTAAACTG ATAGCGTGAT CAGCATGCAA
	GAGAAAGATG

3901	ATTCTTGAAG CATACGATAA CAGATTGAAT GTGACAAAAA
	GTTTGTGTCT

3951	CAGCTTCAGG GTCGGCACCT AATACAAAAG GAAAATTTGT
	CAGGTTTCCT

4001	TCCGTAGTTT CATTCACTAT TATTGAATCC TTTGGCTACC
	ATTCTTGAGA

4051	AACACAAACA CTTCTTATAT CTGTTCTACA CAATTCTCTG
	AGTGCGTGCC

4101	ACAGTTTGGT ATCTTCATGA TTGCTCATTG TTCATGCCCA
	TAAGGAACAT

4151	GTAACTTCCT CATTTATTTA TTATTGCTTT TGTTTTCTTC
	TCACTAGTTA

4201	ACTTTCGTTT CCCTATATAA ACCCTCCTTT GTTCCCTTCC
	CTTCCCATCT

4251	TCCATTTATT GATTCCAAAC ACAAACCTCG AGAAAATGGC
	TTCTATGATA

4301	TCCTCTTCCG CTGTGACAAC AGTCAGCCGT GCCTCTAGGG
	GGCAATCCGC

4351	CGCAGTGGCT CCATTCGGCG GCCTCAAATC CATGACTGGA
	TTCCCAGTGA

4401	AGAAGGTCAA CACTGACATT ACTTCCATTA CAAGCAATGG
	TGGAAGAGTA

4451	AAGTGCATGC AGGTGTGGCC TCCAATTGGA AAGAAGAAGT
	TTGAGACTCT

4501	TTCCTATTTG CCACCATTGA CGAGAGATTC TAGAGTGCTC
	TACCAATTGC

4551	ATGAGTTCCA GCGCTCGATC CTGCACCCGC TGACCGCGTG
	GGCCCAGGCG

4601	ACCGCCAAGA CCTTCACCAA CCCCCTCAGC CCGCTCTCGC
	TGGTTCCCGG

4651	CGCACCCCGC CTGGCTGCCG GCTATGAACT GCTGTACCGG
	CTCGGCAAGG

4701	AATACGAAAA GCCGGCATTC GACATCAAGT CGGTGCGCTC
	CAACGGGCGC

4751	GACATCCCCA TCGTCGAGCA GACCGTGCTT GAAAAGCCGT
	TCTGCAAGCT

4801	GGTGCGCTTC AAGCGCTATG CCGACGACCC GGAGACCATC
	AAGCTGCTCA

4851	AGGATGAGCC GGTGGTGCTG GTGGCCGCGC CGCTGTCGGG
	CCACCATGCC

4901	ACGCTGCTGC GCGACACGGT GCGCACGCTG CTCCAGGACC
	ACAAGGTCTA

4951	CGTCACCGAC TGGATCGACG CACGCATGGT GCCGGTCGAG
	GAAGGCGCGT

5001	TCCACCTGTC GGACTACATC TACTACATCC AGGAGTTCAT
	CCGCCATATC

5051	GGCGCCGAGA ACCTGCATGT GATCTCGGTA TGCCAGCCCA
	CCGTGCCGGT

5101	GCTGGCCGCG ATCTCGCTGA TGGCCTCGGC CGGCGAGAAG
	ACGCCGCGCA

5151	CCATGACCAT GATGGGCGGC CCGATCGACG CCCGCAAGAG
	CCCCACGGCG

5201	GTCAACTCGC TGGCGACCAA CAAGTCGTTC GAGTGGTTCG
	AGAACAACGT

5251	CATCTACACC GTGCCGGCCA ACTACCCCGG CCACGGCCGC
	CGCGTCTACC

5301	CAGGCTTTTT GCAGCATGCC GGTTTCGTGG CGATGAACCC
	GGACCGGCAC

5351	CTTTCCTCGC ACTATGACTT CTACCTGAGC CTGGTCGAGG
	GCGATGCGGA

5401	TGACGCCGAA GCCCACGTGC GCTTCTACGA CGAATACAAC
	GCGGTGCTCG

5451	ACATGGCCGC CGAGTACTAC CTCGACACCA TCCGCGAGGT
	GTTCCAGGAG

5501	TTCCGCCTGG CCAACGGCAC CTGGGCCATC GACGGCAATC
	CGGTCCGGCC

5551	GCAGGACATC AAGAGCACCG CGCTGATGAC CGTCGAGGGC
	GAACTGGACG

5601	ACATCTCGGG CGCGGGCCAG ACCGCAGCGG CGCACGACCT
	GTGCGCCGGC

5651	ATCCCGAAAA TCCGCAAGCA GCACCTGAAC GCGGCACACT
	GCGGCCACTA

5701	CGGCATCTTC TCGGGCCGGC GCTGGCGCGA AGAGATATAC
	CCGCAGCTGC

5751	GCGACTTTAT CCGCAAGTAC CACCAGGCCT CGGCCACCAG
	GTAAGAGCTC

5801	GAATTGATCC TCTAGAGCTT TCGTTCGTAT CATCGGTTTC
	GACAACGTTC

5851	GTCAAGTTCA ATGCATCAGT TTCATTGCGC ACACACCAGA
	ATCCTACTGA

5901	GTTCGAGTAT TATGGCATTG GGAAAACTGT TTTTCTTGTA
	CCATTTGTTG

5951	TGCTTGTAAT TTACTGTGTT TTTTATTCGG TTTTCGCTAT
	CGAACTGTGA

6001	AATGGAAATG GATGGAGAAG AGTTAATGAA TGATATGGTC
	CTTTTGTTCA

6051	TTCTCAAATT AATATTATTT GTTTTTTCTC TTATTTGTTG
	TGTGTTGAAT

6101	TTGAAATTAT AAGAGATATG CAAACATTTT GTTTTGAGTA
	AAAATGTGTC

6151	AAATCGTGGC CTCTAATGAC CGAAGTTAAT ATGAGGAGTA
	AAACACTTGT

6201	AGTTGTACCA TTATGCTTAT TCACTAGGCA ACAAATATAT
	TTTCAGACCT

6251	AGAAAAGCTG CAAATGTTAC TGAATACAAG TATGTCCTCT
	TGTGTTTTAG

6301	ACATTTATGA ACTTTCCTTT ATGTAATTTT CCAGAATCCT
	TGTCAGATTC

6351	TAATCATTGC TTTATAATTA TAGTTATACT CATGGATTTG
	TAGTTGAGTA

6401	TGAAAATATT TTTTAATGCA TTTTATGACT TGCCAATTGA
	TTGACAACAT

6451	GCATCAGTCG ACCTGAGGTA ATTATAACCC GGGCCCTATA
	TATGGATCCA

6501	ACTTTTGAGG CAGAGCTTGT AAATTGTAAC ACCTGAGGTA
	GAAAGACGGA

6551	AAGTACTTTT AATAATAAAA GGTTTGAAAA ATTAAGAAAA
	GAAGAAGAAA

6601	ATATTTTGTG AGTGCACGCG ATGGATCTAA TCCTTCCATG
	AAAAAGAATA

6651	TCAAGAATAA CAAAAATTGA CAAAATCAGC GAATACTTCA
	CCCAAAAGTC

6701	TACACAATAA TAAATGCTAA ATCACATATA ATTTGTGATG
	CATAACGCAT

6751	TACGCTATCG TAATCCTTTA CAACAAGCAA GAACGTCATC
	CCAGAATCTC

6801	AACTCAAATC AAAACCGTTC ATTCATAAAT AAAAAATATT
	CTTACATTCT

6851	TTTGCAAATA GAACCTTTGC CAAATTGAAA TAACAAACTC
	TAGGTATTTG

6901	TCAAATTAAC TTACCAACTT CTCGTTATAT AATTTTAGAT
	TTATAATCAT

6951	GTCTATAAAT TATTTCTATA CACTCTCTCT CAAATTTGAC
	CTTTACATTC

7001	TGTGATTTAT TTGAACAGAA TAAATCACTG TAAAACTAAA
	CAACTCTTTA

7051	AAAAAGGTAA ATTAGGAAAA GTCGAAATCA ATAAATTATA
	AATCAATCCC

7101	TAGAAAACTG CAAGATAATA TTCTTACCAA AATCATTTAA
	ATAAATTTGT

7151	AAGTTTTTTC TTTATACCAA TTTTCTGAGA CCCAGAGACA
	TTCTTAAATT

7201	CATAACAACG GTTTTAAGTA TCAGAGTATA ACATCTTTGT
	ATAAATAGAT

7251	TTTTGAACGT TCAATAACTA ACACGTCAGT TTTTGTTTCC
	ACGTTGTACG

7301	TTTAATAACA ATAAATGCGT GAGTTAGATT ACTAATCAGA
	AGTTAGAAGT

7351	GTACAAGACT AACTTTATAC AGAAATATAT TGTTTCAGAC
	TGCACTTTAT

7401	GGTGCGTAGC ACCTCAAAAC TCTTACCTTT CGCATACATT
	TTCACACTTC

7451	ATCCAAACCT TTCGAAAAGT CACTTCCCTT ATATTAAAGG
	ACTATGATAT

7501	AAAAAAGACT ATATGTGTTA CTAATTTATT GGTTTGTATA
	TTTGTAATAA

7551	ATCGTTCCAT CAAGAGGAGC TATCACATAT TGAGAACAGT
	AAAAAAAAAA

7601	AAAAGTTGGT AAAAAAACAT TTTCTTATAT TATATCATAA
	AATCAGTTAC

7651	CATAGTATTT TAGAGTTTTC AGAATAATGC TTCACCCAAC
	TTGCAACTCA

7701	TTGTGCCTCA AAACAGGACG TAACCATGTT ACTCACTCTC
	CTGCACAACC

7751	CCTTGTTAAA CTGATAGCGT GATCAGCATG CAAGAGAAAG
	ATGATTCTTG

7801	AAGCATACGA TAACAGATTG AATGTGACAA AAAGTTTGTG
	TCTCAGCTTC

7851	AGGGTCGGCA CCTAATACAA AAGGAAAATT TGTCAGGTTT
	CCTTCCGTAG

7901	TTTCATTCAC TATTATTGAA TCCTTTGGCT ATGATTCTTG
	AGAAACACAA

7951	ACACTTCTTA TATCTGTTCT ACACAATTCT CTGAGTGCGT
	GCCACAGTTT

8001	GAATACTTCA TGATTGCTCA TTGTTCATGC CCATAAGGAA
	CATGTAACTT

8051	CCTCATTTAT TTATTATTGC TTTTGTTTTC TTCTCACTAG
	TTAACTTTCG

8101	TTTCCCTATA TAAACCCTCC TTTGTTCCCT TCCCTTCCCA
	TCTTCCATTT

8151	ATTGATTCCA AACACAAACC TCGAGAAAAT GGCTTCTATG
	ATATCCTCTT

8201	CCGCTGTGAC AACAGTCAGC CGTGCCTCTA GGGGGCAATC
	CGCCGCAGTG

8251	GCTCCATTCG GCGGCCTCAA ATCCATGACT GGATTCCCAG
	TGAAGAAGGT

8301	CAACACTGAC ATTACTTCCA TTACAAGCAA TGGTGGAAGA
	GTAAAGTGCA

8351	TGCAGGTGTG GCCTCCAATT GGAAAGAAGA AGTTTGAGAC
	TCTTTCCTAT

8401	TTGCCACCAT TGACGAGAGA TTCTAGAGTG CTCAAAGGAA
	AAGTCGCAGT

8451	CGTCACCGGT TCCACCAGCG GGATCGGCCT GGGTATCGCC
	ACCGCGCTGG

8501	CCGCGCAGGG CGCCGATATC GTCCTGAACG GCTTCGGCGA
	CGCCGCCGAG

8551	ATCGAAAAGG TGCGCGCCGG CCTGGCCGCC CAGCATGGCG
	TCAAGGTGCT

8601	GTACGACGGC GCCGACCTGT CCAAGGGCGA GGCCGTGCGC
	GGCCTGGTGG

8651	ACAACGCGGT GCGCCAGATG GGCCGCATCG ACATCCTGGT
	CAACAACGCC

8701	GGCATCCAGC ACACCGCGCT GATCGAGGAC TTTCCCACCG
	AAAAATGGGA

8751	CGCCATCCTG GCGCTGAACC TGTCGGCCGT GTTCCACGGC
	ACCGCCGCCG

8801	CGCTGCCGCA CATGAAGAAG CAGGGCTTCG GCCGCATCAT
	CAACATCGCC

8851	TCGGCGCACG GCCTGGTGGC CTCGGCCAAC AAGTCGGCCT
	ACGTCGCCGC

8901	CAAGCACGGC GTGGTGGGCT TCACCAAGGT GACCGCGCTG
	GAAACCGCCG

8951	GCCAGGGCAT CACCGCCAAC GCCATCTGCC CAGGCTGGGT
	GCGCACTCCG

9001	CTGGTCGAAA AGCAGATATC GGCGCTGGCC GAAAAGAACG
	GCGTGGACCA

9051	GGAAACCGCC GCGCGCGAAC TGCTCAGCGA AAAGCAGCCG
	TCGCTGCAAT

9101	TCGTCACGCC CGAACAACTG GGCGGCACGG CCGTCTTCCT
	GGCCTCCGAT

9151	GCCGCCGCGC AAATCACCGG CACGACCGTC TCCGTCGATG
	GCGGCTGGAC

9201	GGCGCGCTGA GAGCTCGCTT TCGTTCGTAT CATCGGTTTC
	GACAACGTTC

9251	GTCAAGTTCA ATGCATCAGT TTCATTGCGC ACACACCAGA
	ATCCTACTGA

9301	GTTCGAGTAT TATGGCATTG GGAAAACTGT TTTTCTTGTA
	CCATTTGTTG

9351	TGCTTGTAAT TTACTGTGTT TTTTATTCGG TTTTCGCTAT
	CGAACTGTGA

9401	AATGGAAATG GATGGAGAAG AGTTAATGAA TGATATGGTC
	CTTTTGTTCA

9451	TTCTCAAATT AATATTATTT GTTTTTTCTC TTATTTGTTG
	TGTGTTGAAT

9501	TTGAAATTAT AAGAGATATG CAAACATTTT GTTTTGAGTA
	AAAATGTGTC

9551	AAATCGTGGC CTCTAATGAC CGAAGTTAAT ATGAGGAGTA
	AAACACTTGT

9601	AGTTGTACCA TTATGCTTAT TCACTAGGCA ACAAATATAT
	TTTCAGACCT

9651	AGAAAAGCTG CAAATGTTAC TGAATACAAG TATGTCCTCT
	TGTGTTTTAG

9701	ACATTTATGA ACTTTCCTTT ATGTAATTTT CCAGAATCCT
	TGTCAGATTC

9751	TAATCATTGC TTTATAATTA TAGTTATACT CATGGATTTG
	TAGTTGAGTA

9801	TGAAAATATT TTTTAATGCA TTTTATGACT TGCCAATTGA
	TTGACAACAT

9851	GCATCAGCTA GTAGAAGGTA ATTATCCAAG ATGTAGCATC
	AAGAATCCAA

9901	TGTTTACGGG AAAAACTATG GAAGTATTAT GTGAGCTCAG
	CAAGAAGCAG

9951	ATCAATATGC GGCACATATG CAACCTATGT TCAAAAATGA
	AGAATGTACA

10001	GATACAAGAT CCTATACTGC CAGAATACGA AGAAGAATAC
	GTAGAAATTG

10051	AAAAAGAAGA ACCAGGCGAA GAAAAGAATC TTGAAGACGT
	AAGCACTGAC

10101	GACAACAATG AAAAGAAGAA GATAAGGTCG GTGATTGTGA
	AAGAGACATA

10151	GAGGACACAT GTAAGGTGGA AAATGTAAGG GCGGAAAGTA
	ACCTTATCAC

10201	AAAGGAATCT TATCCCCCAC TACTTATCCT TTTATATTTT
	TCCGTGTCAT

10251	TTTTGCCCTT GAGTTTTCCT ATATAAGGAA CCAAGTTCGG
	CATTTGTGAA

10301	AACAAGAAAA AATTGGTGTA AGCTATTTTC TTTGAAGTAC
	TGAGGATACA

10351	ACTTCAGAGA AATTTGTAAG AAAGTGGATC GAAACCATGG
	CCTCCTCCGA

10401	GAACGTCATC ACCGAGTTCA TGCCCTTCAA GGTGCGCATG
	CAGGGCACCG

10451	TGAACGGCCA CGAGTTCGAG ATCGAGGGCG AGGGCGAGGG
	CCGCCCCTAC

10501	GAGGGCCACA ACACCGTGAA GCTGAAGGTG ACCAAGGGCG
	GCCCCCTGCC

10551	CTTCGCCTGG GACATCCTGT CCCCCCAGTT CCAGTACGGC
	TCCAAGGTGT

10601	ACGTGAAGCA CCCCGCCGAC ATCCCCGACT ACAAGAAGCT
	GTCCTTCCCC

10651	GAGGGCTTCA AGTGGGAGCG CGTGATGAAC TTCGAGGACG
	GCGGCGTGGC

10701	GACCGTGACC CAGGACTCCT CCCTGCAGGA CGGCTGCTTC
	ATCTACAAGG

10751	TGAAGTTCAT CGGCGTGAAC TTCCCCTCCG ACGGCCCCGT
	GATGCAGAAG

10801	AAGACCATGG GCTGGGAGGC CTCCACCGAG CGCCTGTACC
	CCCGCGACGG

10851	CGTGCTGAAG GGCGAGACCC ACAAGGCCCT GAAGCTGAAG
	GACGGCGGCC

10901	ACTACCTGGT GGAGTTCAAG TCCATCTACA TGGCCAAGAA
	GCCCGTGCAG

10951	CTGCCCGGCT ACTACTACGT GGACGCCAAG CTGGACATCA
	CCTCCCACAA

11001	CGAGGACTAC ACCATCGTGG AGCAGTACGA GCGCACCGAG
	GGCCGCCACC

11051	ACCTGTTCCT GGTACCAATG AGCTCTGTCC AACAGTCTCA
	GGGTTAATGT

11101	CTATGTATCT TAAATAATGT TGTCGGCGAT CGTTCAAACA
	TTTGGCAATA

11151	AAGTTTCTTA AGATTGAATC CTGTTGCCGG TCTTGCGATG
	ATTATCATAT

11201	AATTTCTGTT GAATTACGTT AAGCATGTAA TAATTAACAT
	GTAATGCATG

11251	ACGTTATTTA TGAGATGGGT TTTTATGATT AGAGTCCCGC
	AATTATACAT

11301	TTAATACGCG ATAGAAAACA AAATATAGCG CGCAAACTAG
	GATAAATTAT

11351	CGCGCGCGGT GTCATCTATG TTACTAGATC GGGAATTAAA
	CTATCAGTGT

11401	TTGACAGGAT ATATTGGCGG GTAAACCTAA GAGAAAAGAG
	CGTTTATTAG

11451	AATAACGGAT ATTTAAAAGG GCGTGAAAAG GTTTATCCGT
	TCGTCCATTT

11501	GTATGTGCAT GCCAACCACA GGGTTCCCCT CGGGATCAAA
	GTACTTTGAT

11551	CCAACCCCTC CGCTGCTATA GTGCAGTCGG CTTCTGACGT
	TCAGTGCAGC

11601	CGTCTTCTGA AAACGACATG TCGCACAAGT CCTAAGTTAC
	GCGACAGGCT

11651	GCCGCCCTGC CCTTTTCCTG GCGTTTTCTT GTCGCGTGTT
	TTAGTCGCAT

11701	AAAGTAGAAT ACTTGCGACT AGAACCGGAG ACATTACGCC
	ATGAACAAGA

11751	GCGCCGCCGC TGGCCTGCTG GGCTATGCCC GCGTCAGCAC
	CGACGACCAG

11801	GACTTGACCA ACCAACGGGC CGAACTGCAC GCGGCCGGCT
	GCACCAAGCT

11851	GTTTTCCGAG AAGATCACCG GCACCAGGCG CGACCGCCCG
	GAGCTGGCCA

11901	GGATGCTTGA CCACCTACGC CCTGGCGACG TTGTGACAGT
	GACCAGGCTA

11951	GACCGCCTGG CCCGCAGCAC CCGCGACCTA CTGGACATTG
	CCGAGCGCAT

12001	CCAGGAGGCC GGCGCGGGCC TGCGTAGCCT GGCAGAGCCG
	TGGGCCGACA

12051	CCACCACGCC GGCCGGCCGC ATGGTGTTGA CCGTGTTCGC
	CGGCATTGCC

12101	GAGTTCGAGC GTTCCCTAAT CATCGACCGC ACCCGGAGCG
	GGCGCGAGGC

12151	CGCCAAGGCC CGAGGCGTGA AGTTTGGCCC CCGCCCTACC
	CTCACCCCGG

12201	CACAGATCGC GCACGCCCGC GAGCTGATCG ACCAGGAAGG
	CCGCACCGTG

12251	AAAGAGGCGG CTGCACTGCT TGGCGTGCAT CGCTCGACCC
	TGTACCGCGC

12301	ACTTGAGCGC AGCGAGGAAG TGACCCCCAC CGAGGCCAGG
	CGGCGCGGTG

12351	CCTTCCGTGA GGACGCATTG ACCGAGGCCG ACGCCCTGGC
	GGCCGCCGAG

12401	AATGAACGCC AAGAGGAACA AGCATGAAAC CGCACCAGGA
	CGGCCAGGAC

12451	GAACCGTTTT TCATTACCGA AGAGATCGAG GCGGAGATGA
	TCGCGGCCGG

12501	GTACGTGTTC GAGCCGCCCG CGCACGTCTC AACCGTGCGG
	CTGCATGAAA

12551	TCCTGGCCGG TTTGTCTGAT GCCAAGCTGG CGGCCTGGCC
	GGCCAGCTTG

12601	GCCGCTGAAG AAACCGAGCG CCGCCGTCTA AAAAGGTGAT
	GTGTATTTGA

12651	GTAAAACAGC TTGCGTCATG CGGTCGCTGC GTATATGATG
	CGATGAGTAA

12701	ATAAACAAAT ACGCAAGGGG AACGCATGAA GGTTATCGCT
	GTACTTAACC

12751	AGAAAGGCGG GTCAGGCAAG ACGACCATCG CAACCCATCT
	AGCCCGCGCC

12801	CTGCAACTCG CCGGGGCCGA TGTTCTGTTA GTCGATTCCG
	ATCCCCAGGG

12851	CAGTGCCCGC GATTGGGCGG CCGTGCGGGA AGATCAACCG
	CTAACCGTTG

12901	TCGGCATCGA CCGCCCGACG ATTGACCGCG ACGTGAAGGC
	CATCGGCCGG

12951	CGCGACTTCG TCGGCATCGA CGGAGCGCCC CAGGCGGCGG
	ACTTGGCTGT

13001	GTCCGCGATC AAGGCAGCCG ACTTCGTGCT GATTCCGGTG
	CAGCCAAGCC

13051	CTTACGACAT ATGGGCCACC GCCGACCTGG TGGAGCTGGT
	TAAGCAGCGC

13101	ATTGAGGTCA CGGATGGAAG GCTACAAGCG GCCTTTGTCG
	TGTCGCGGGC

13151	GATCAAAGGC ACGCGCATCG GCGGTGAGGT TGCCGAGGCG
	CTGGCCGGGT

13201	ACGAGCTGCC CATTCTTGAG TCCCGTATCA CGCAGCGCGT
	GAGCTACCCA

13251	GGCACTGCCG CCGCCGGCAC AACCGTTCTT GAATCAGAAC
	CCGAGGGCGA

13301	CGCTGCCCGC GAGGTCCAGG CGCTGGCCGC TGAAATTAAA
	TCAAAACTCA

13351	TTTGAGTTAA TGAGGTAAAG AGAAAATGAG CAAAAGCACA
	AACACGCTAA

13401	GTGCCGGCCG TCCGAGCGCA CGCAGCAGCA AGGCTGCAAC
	GTTGGCCAGC

13451	CTGGCAGACA CGCCAGCCAT GAAGCGGGTC AACTTTCAGT
	TGCCGGCGGA

13501	GGATCACACC AAGCTGAAGA TGTACGCGGT ACGCCAAGGC
	AAGACCATTA

13551	CCGAGCTGCT ATCTGAATAC ATCGCGCAGC TACCAGAGTA
	AATGAGCAAA

13601	TGAATAAATG AGTAGATGAA TTTTAGCGGC TAAAGGAGGC
	GGCATGGAAA

13651	ATCAAGAACA ACCAGGCACC GACGCCGTGG AATGCCCCAT
	GTGTGGAGGA

13701	ACGGGCGGTT GGCCAGGCGT AAGCGGCTGG GTTGTCTGCC
	GGCCCTGCAA

13751	TGGCACTGGA ACCCCCAAGC CCGAGGAATC GGCGTGACGG
	TCGCAAACCA

13801	TCCGGCCCGG TACAAATCGG CGCGGCGCTG GGTGATGACC
	TGGTGGAGAA

13851	GTTGAAGGCC GCGCAGGCCG CCCAGCGGCA ACGCATCGAG
	GCAGAAGCAC

13901	GCCCCGGTGA ATCGTGGCAA GCGGCCGCTG ATCGAATCCG
	CAAAGAATCC

13951	CGGCAACCGC CGGCAGCCGG TGCGCCGTCG ATTAGGAAGC
	CGCCCAAGGG

14001	CGACGAGCAA CCAGATTTTT TCGTTCCGAT GCTCTATGAC
	GTGGGCACCC

14051	GCGATAGTCG CAGCATCATG GACGTGGCCG TTTTCCGTCT
	GTCGAAGCGT

14101	GACCGACGAG CTGGCGAGGT GATCCGCTAC GAGCTTCCAG
	ACGGGCACGT

14151	AGAGGTTTCC GCAGGGCCGG CCGGCATGGC CAGTGTGTGG
	GATTACGACC

14201	TGGTACTGAT GGCGGTTTCC CATCTAACCG AATCCATGAA
	CCGATACCGG

14251	GAAGGGAAGG GAGACAAGCC CGGCCGCGTG TTCCGTCCAC
	ACGTTGCGGA

14301	CGTACTCAAG TTCTGCCGGC GAGCCGATGG CGGAAAGCAG
	AAAGACGACC

14351	TGGTAGAAAC CTGCATTCGG TTAAACACCA CGCACGTTGC
	CATGCAGCGT

14401	ACGAAGAAGG CCAAGAACGG CCGCCTGGTG ACGGTATCCG
	AGGGTGAAGC

14451	CTTGATTAGC CGCTACAAGA TCGTAAAGAG CGAAACCGGG
	CGGCCCGAGT

14501	ACATCGAGAT CGAGCTAGCT GATTGGATGT ACCGCGAGAT
	CACAGAAGGC

14551	AAGAACCCGG ACGTGCTGAC GGTTCACCCC GATTACTTTT
	TGATCGATCC

14601	CGGCATCGGC CGTTTTCTCT ACCGCCTGGC ACGCCGCGCC
	GCAGGCAAGG

14651	CAGAAGCCAG ATGGTTGTTC AAGACGATCT ACGAACGCAG
	TGGCAGCGCC

14701	GGAGAGTTCA AGAAGTTCTG TTTCACCGTG CGCAAGCTGA
	TCGGGTCAAA

14751	TGACCTGCCG GAGTACGATT TGAAGGAGGA GGCGGGGCAG
	GCTGGCCCGA

14801	TCCTAGTCAT GCGCTACCGC AACCTGATCG AGGGCGAAGC
	ATCCGCCGGT

14851	TCCTAATGTA CGGAGCAGAT GCTAGGGCAA ATTGCCCTAG
	CAGGGGAAAA

14901	AGGTCGAAAA GGTCTCTTTC CTGTGGATAG CACGTACATT
	GGGAACCCAA

14951	AGCCGTACAT TGGGAACCGG AACCCGTACA TTGGGAACCC
	AAAGCCGTAC

15001	ATTGGGAACC GGTCACACAT GTAAGTGACT GATATAAAAG
	AGAAAAAAGG

15051	CGATTTTTCC GCCTAAAACT CTTTAAAACT TATTAAAACT
	CTTAAAACCC

15101	GCCTGGCCTG TGCATAACTG TCTGGCCAGC GCACAGCCGA
	AGAGCTGCAA

15151	AAAGCGCCTA CCCTTCGGTC GCTGCGCTCC CTACGCCCCG
	CCGCTTCGCG

15201	TCGGCCTATC GCGGCCGCTG GCCGCTCAAA AATGGCTGGC
	CTACGGCCAG

15251	GCAATCTACC AGGGCGCGGA CAAGCCGCGC CGTCGCCACT
	CGACCGCCGG

15301	CGCCCACATC AAGGCACCCT GCCTCGCGCG TTTCGGTGAT
	GACGGTGAAA

15351	ACCTCTGACA CATGCAGCTC CCGGAGACGG TCACAGCTTG
	TCTGTAAGCG

15401	GATGCCGGGA GCAGACAAGC CCGTCAGGGC GCGTCAGCGG
	GTGTTGGCGG

15451	GTGTCGGGGC GCAGCCATGA CCCAGTCACG TAGCGATAGC
	GGAGTGTATA

15501	CTGGCTTAAC TATGCGGCAT CAGAGCAGAT TGTACTGAGA
	GTGCACCATA

15551	TGCGGTGTGA AATACCGCAC AGATGCGTAA GGAGAAAATA
	CCGCATCAGG

15601	CGCTCTTCCG CTTCCTCGCT CACTGACTCG CTGCGCTCGG
	TCGTTCGGCT

15651	GCGGCGAGCG GTATCAGCTC ACGCCAAGGC GGTAATACGG
	TTATCCACAG

15701	AATCAGGGGA TAACGCAGGA AAGAACATGT GAGCAAAAGG
	CCAGCAAAAG

15751	GCCAGGAACC GTAAAAAGGC CGCGTTGCTG GCGTTTTTCC
	ATAGGCTCCG

15801	CCCCCCTGAC GAGCATCACA AAAATCGACG CTCAAGTCAG
	AGGTGGCGAA

15851	ACCCGACAGG ACTATAAAGA TACCAGGCGT TTCCCCCTGG
	AAGCTCCCTC

15901	GTGCGCTCTC CTGTTCCGAC CCTGCCGCTT ACCGGATACC
	TGTCCGCCTT

15951	TCTCCCTTCG GGAAGCGTGG CGCTTTCTCA TAGCTCACGC
	TGTAGGTATC

16001	TCAGTTCGGT GTAGGTCGTT CGCTCCAAGC TGGGCTGTGT
	GCACGAACCC

16051	CCCGTTCAGC CCGACCGCTG CGCCTTATCC GGTAACTATC
	GTCTTGAGTC

16101	CAACCCGGTA AGACACGACT TATCGCCACT GGCAGCAGCC
	ACTGGTAACA

16151	GGATTAGCAG AGCGAGGTAT GTAGGCGGTG CTACAGAGTT
	CTTGAAGTGG

16201	TGGCCTAACT ACGGCTACAC TAGAAGGACA GTATTTGGTA
	TCTGCGCTCT

16251	GCTGAAGCCA GTTACCTTCG GAAAAAGAGT TGGTAGCTCT
	TGATCCGGCA

16301	AACAAACCAC CGCTGGTAGC GGTGGTTTTT TTGTTTGCAA
	GCAGCAGATT

16351	ACGCGCAGAA AAAAAGGATC TCAAGAAGAT CCTTTGATCT
	TTTCTACGGG

16401	GTCTGACGCT CAGTGGAACG AAAACTCACG TTAAGGGATT
	TTGGTCATGC

16451	ATTCTAGGTA CTAAAACAAT TCATCCAGTA AAATATAATA
	TTTTATTTTC

16501	TCCCAATCAG GCTTGATCCC CAGTAAGTCA AAAAATAGCT
	CGACATACTG

16551	TTCTTCCCCG ATATCCTCCC TGATCGACCG GACGCAGAAG
	GCAATGTCAT

16601	ACCACTTGTC CGCCCTGCCG CTTCTCCCAA GATCAATAAA
	GCCACTTACT

16651	TTGCCATCTT TCACAAAGAT GTTGCTGTCT CCCAGGTCGC
	CGTGGGAAAA

16701	GACAAGTTCC TCTTCGGGCT TTTCCGTCTT TAAAAAATCA
	TACAGCTCGC

16751	GCGGATCTTT AAATGGAGTG TCTTCTTCCC AGTTTTCGCA
	ATCCACATCG

16801	GCCAGATCGT TATTCAGTAA GTAATCCAAT TCGGCTAAGC
	GGCTGTCTAA

16851	GCTATTCGTA TAGGGACAAT CCGATATGTC GATGGAGTGA
	AAGAGCCTGA

16901	TGCACTCCGC ATACAGCTCG ATAATCTTTT CAGGGCTTTG
	TTCATCTTCA

16951	TACTCTTCCG AGCAAAGGAC GCCATCGGCC TCACTCATGA
	GCAGATTGCT

17001	CCAGCCATCA TGCCGTTCAA AGTGCAGGAC CTTTGGAACA
	GGCAGCTTTC

17051	CTTCCAGCCA TAGCATCATG TCCTTTTCCC GTTCCACATC
	ATAGGTGGTC

17101	CCTTTATACC GGCTGTCCGT CATTTTTAAA TATAGGTTTT
	CATTTTCTCC

17151	CACCAGCTTA TATACCTTAG CAGGAGACAT TCCTTCCGTA
	TCTTTTACGC

17201	AGCGGTATTT TTCGATCAGT TTTTTCAATT CCGGTGATAT
	TCTCATTTTA

17251	GCCATTTATT ATTTCCTTCC TCTTTTCTAC AGTATTTAAA
	GATACCCCAA

17301	GAAGCTAATT ATAACAAGAC GAACTCCAAT TCACTGTTCC
	TTGCATTCTA

17351	AAACCTTAAA TACCAGAAAA CAGCTTTTTC AAAGTTGTTT
	TCAAAGTTGG

17401	CGTATAACAT AGTATCGACG GAGCCGATTT TGAAACCGCG
	GTGATCACAG

17451	GCAGCAACGC TCTGTCATCG TTACAATCAA CATGCTACCC
	TCCGCGAGAT

17501	CATCCGTGTT TCAAACCCGG CAGCTTAGTT GCCGTTCTTC
	CGAATAGCAT

17551	CGGTAACATG AGCAAAGTCT GCCGCCTTAC AACGGCTCTC
	CCGCTGACGC

17601	CGTCCCGGAC TGATGGGCTG CCTGTATCGA GTGGTGATTT
	TGTGCCGAGC

17651	TGCCGGTCGG GGAGCTGTTG GCTGGCTGGT GGCAGGATAT
	ATTGTGGTGT

17701	AAACAAATTG ACGCTTAGAC AACTTAATAA CACATTGCGG
	ACGTTTTTAA

17751	TGTACTGAAT TAACGCCGAA TTAATTCCTA GGCCACCATG
	TTGGGCCCGG

17801	GGCGCGCCGT ACGTAGTGTT TATCTTTGTT GCTTTTCTGA
	ACAATTTATT

17851	TACTATGTAA ATATATTATC AATGTTTAAT CTATTTTAAT
	TTGCACATGA

17901	ATTTTCATTT TATTTTTACT TTACAAAACA AATAAATATA
	TATGCAAAAA

17951	AATTTACAAA CGATGCACGG GTTACAAACT AATTTCATTA
	AATGCTAATG

18001	CAGATTTTGT GAAGTAAAAC TCCAATTATG ATGAAAAATA
	CCACCAACAC

18051	CACCTGCGAA ACTGTATCCC AACTGTCCTT AATAAAAATG
	TTAAAAAGTA

18101	TATTATTCTC ATTTGTCTGT CATAATTTAT GTACCCCACT
	TTAATTTTTC

18151	TGATGTACTA AACCGAGGGC AAACTGAAAC CTGTTCCTCA
	TGCAAAGCCC

18201	CTACTCACCA TGTATCATGT ACGTGTCATC ACCCAACAAC
	TCCACTTTTG

18251	CTATATAACA ACACCCCCGT CACACTCTCC CTCTCTAACA
	CACACCCCAC

18301	TAACAATTCC TTCACTTGCA GCACTGTTGC ATCATCATCT
	TCATTGCAAA

18351	ACCCTAAACT TCACCTTCAA CCGCGGCCGC ATGGCTTCTA
	TGATATCCTC

18401	TTCCGCTGTG ACAACAGTCA GCCGTGCCTC TAGGGGGCAA
	TCCGCCGCAG

18451	TGGCTCCATT CGGCGGCCTC AAATCCATGA CTGGATTCCC
	AGTGAAGAAG

18501	GTCAACACTG ACATTACTTC CATTACAAGC AATGGTGGAA
	GAGTAAAGTG

18551	CATGCAGGTG TGGCCTCCAA TTGGAAAGAA GAAGTTTGAG
	ACTCTTTCCT

18601	ATTTGCCACC ATTGACGAGA GATTCTAGAG TGAGTAACAA
	GAACAACGAT

18651	GAGCTGCAGT GGCAATCCTG GTTCAGCAAG GCGCCCACCA
	CCGAGGCGAA

18701	CCCGATGGCC ACCATGTTGC AGGATATCGG CGTTGCGCTC
	AAACCGGAAG

18751	CGATGGAGCA GCTGAAAAAC GATTATCTGC GTGACTTCAC
	CGCGTTGTGG

18801	CAGGATTTTT TGGCTGGCAA GGCGCCAGCC GTCAGCGACC
	GCCGCTTCAG

18851	CTCGGCAGCC TGGCAGGGCA ATCCGATGTC GGCCTTCAAT
	GCCGCATCTT

18901	ACCTGCTCAA CGCCAAATTC CTCAGTGCCA TGGTGGAGGC
	GGTGGACACC

18951	GCACCCCAGC AAAAGCAGAA AATACGCTTT GCCGTGCAGC
	AGGTGATTGA

19001	TGCCATGTCG CCCGCGAACT TCCTCGCCAC CAACCCGGAA
	GCGCAGCAAA

19051	AACTGATTGA AACCAAGGGC GAGAGCCTGA CGCGTGGCCT
	GGTCAATATG

19101	CTGGGCGATA TCAACAAGGG CCATATCTCG CTGTCGGACG
	AATCGGCCTT

19151	TGAAGTGGGC CGCAACCTGG CCATTACCCC GGGCACCGTG
	ATTTACGAAA

19201	ATCCGCTGTT CCAGCTGATC CAGTACACGC CGACCACGCC
	GACGGTCAGC

19251	CAGCGCCCGC TGTTGATGGT GCCGCCGTGC ATCAACAAGT
	TCTACATCCT

19301	CGACCTGCAA CCGGAAAATT CGCTGGTGCG CTACGCGGTG
	GAGCAGGGCA

19351	ACACCGTGTT CCTGATCTCG TGGAGCAATC CGGACAAGTC
	GCTGGCCGGC

19401	ACCACCTGGG ACGACTACGT GGAGCAGGGC GTGATCGAAG
	CGATCCGCAT

19451	CGTCCAGGAC GTCAGCGGCC AGGACAAGCT GAACATGTTC
	GGCTTCTGCG

19501	TGGGCGGCAC CATCGTTGCC ACCGCACTGG CGGTACTGGC
	GGCGCGTGGC

19551	CAGCACCCGG CGGCCAGCCT GACCCTGCTG ACCACCTTCC
	TCGACTTCAG

19601	CGACACCGGC GTGCTCGACG TCTTCGTCGA TGAAACCCAG
	GTCGCGCTGC

19651	GTGAACAGCA ATTGCGCGAT GGCGGCCTGA TGCCGGGCCG
	TGACCTGGCC

19701	TCGACCTTCT CGAGCCTGCG TCCGAACGAC CTGGTATGGA
	ACTATGTGCA

19751	GTCGAACTAC CTCAAAGGCA ATGAGCCGGC GGCGTTTGAC
	CTGCTGTTCT

19801	GTAATTCGGA CAGCACCAAT TTGCCGGGCC CGATGTTCTG
	CTGGTACCTG

19851	CGCAACACCT ACCTGGAAAA CAGCCTGAAA GTGCCGGGCA
	AGCTGACGGT

19901	GGCCGGCGAA AAGATCGACC TCGGCCTGAT CGACGCCCCG
	GCCTTCATCT

19951	ACGGTTCGCG CGAAGACCAC ATCGTGCCGT GGATGTCGGC
	GTACGGTTCG

20001	CTCGACATCC TCAACCAGGG CAAGCCGGGC GCCAACCGCT
	TCGTGCTGGG

20051	CGCGTCCGGC CATATCGCCG GCGTGATCAA CTCGGTGGCC
	AAGAACAAGC

20101	GCAGCTACTG GATCAACGAC GGTGGCGCCG CCGATGCCCA
	GGCCTGGTTC

20151	GATGCCGCGC AGGAAGTGCC GGGCAGCTGG TGGCCGCAAT
	GGGCCGGGTT

20201	CCTGACCCAG CATGGCGGCA AGAAGGTCAA GCCCAAGGCC
	AAGCCCGGCA

20251	ACGCCCGCTA CACCGCGATC GAGGCGGCGC CCGGCCGTTA
	CGTCAAAGCC

20301	AAGGGCTGAG CGGCCGCTGA GTAATTCTGA TATTAGAGGG
	AGCATTAATG

20351	TGTTGTTGTG ATGTGGTTTA TATGGGGAAA TTAAATAAAT
	GATGTATGTA

20401	CCTCTTGCCT ATGTAGGTTT GTGTGTTTTG TTTTGTTGTC
	TAGCTTTGGT

20451	TATTAAGTAG TAGGGACGTT CGTTCGTGTC TCAAAAAAAG
	GGGTACTACC

20501	ACTCTGTAGT GTATATGGAT GCTGGAAATC AATGTGTTTT
	GTATTTGTTC

20551	ACCTCCATTG TTGAATTCAA TGTCAAATGT GTTTTGCGTT
	GGTTATGTGT

20601	AAAATTACTA TCTTTCTCGT CCGATGATCA AAGTTTTAAG
	CAACAAAACC

20651	AAGGGTGAAA TTTAAACTGT GCTTTGTTGA AGATTCTTTT
	ATCATATTGA

20701	AAATCAAATT ACTAGCAGCA GATTTTACCT AGCATGAAAT
	TTTATCAACA

20751	GTACAGCACT CACTAACCAA GTTCCAAACT AAGATGCGCC
	ATTAACATCA

20801	GCCAATAGGC ATTTTCAGCA AGGCGCGCCC GCGCCGATGT
	ATGTGACAAC

20851	CCTCGGGATT GTTGATTTAT TTCAAAACTA AGAGTTTTTG
	TCTTATTGTT

20901	CTCGTCTATT TTGGATATCA ATCTTAGTTT TATATCTTTT
	CTAGTTCTCT

20951	ACGTGTTAAA TGTTCAACAC ACTAGCAATT TGGCCTGCCA
	GCGTATGGAT

21001	TATGGAACTA TCAAGTCTGT GACGCGCCGT ACGTAGTGTT
	TATCTTTGTT

21051	GCTTTTCTGA ACAATTTATT TACTATGTAA ATATATTATC
	AATGTTTAAT

21101	CTATTTTAAT TTGCACATGA ATTTTCATTT TATTTTTACT
	TTACAAAACA

21151	AATAAATATA TATGCAAAAA AATTTACAAA CGATGCACGG
	GTTACAAACT

21201	AATTTCATTA AATGCTAATG CAGATTTTGT GAAGTAAAAC
	TCCAATTATG

21251	ATGAAAAATA CCACCAACAC CACCTGCGAA ACTGTATCCC
	AACTGTCCTT

21301	AATAAAAATG TTAAAAAGTA TATTATTCTC ATTTGTCTGT
	CATAATTTAT

21351	GTACCCCACT TTAATTTTTC TGATGTACTA AACCGAGGGC
	AAACTGAAAC

21401	CTGTTCCTCA TGCAAAGCCC CTACTCACCA TGTATCATGT
	ACGTGTCATC

21451	ACCCAACAAC TCCACTTTTG CTATATAACA ACACCCCCGT
	CACACTCTCC

21501	CTCTCTAACA CACACCCCAC TAACAATTCC TTCACTTGCA
	GCACTGTTGC

21551	ATCATCATCT TCATTGCAAA ACCCTAAACT TCACCTTCAA
	CCGCGGCCGC

21601	ATGGCTTCTA TGATATCCTC TTCCGCTGTG ACAACAGTCA
	GCCGTGCCTC

21651	TAGGGGGCAA TCCGCCGCAG TGGCTCCATT CGGCGGCCTC
	AAATCCATGA

21701	CTGGATTCCC AGTGAAGAAG GTCAACACTG ACATTACTTC
	CATTACAAGC

21751	AATGGTGGAA GAGTAAAGTG CATGCAGGTG TGGCCTCCAA
	TTGGAAAGAA

21801	GAAGTTTGAG ACTCTTTCCT ATTTGCCACC ATTGACGAGA
	GATTCTAGAG

21851	TGACTCAGCG CATTGCGTAT GTGACCGGCG GCATGGGTGG
	TATCGGAACC

21901	GCCATTTGCC AGCGGCTGGC CAAGGATGGC TTTCGTGTGG
	TGGCCGGTTG

21951	CGGCCCCAAC TCGCCGCGCC GCGAAAAGTG GCTGGAGCAG
	CAGAAGGCCC

22001	TGGGCTTCGA TTTCATTGCC TCGGAAGGCA ATGTGGCTGA
	CTGGGACTCG

22051	ACCAAGACCG CATTCGACAA GGTCAAGTCC GAGGTCGGCG
	AGGTTGATGT

22101	GCTGATCAAC AACGCCGGTA TCACCCGCGA CGTGGTGTTC
	CGCAAGATGA

22151	CCCGCGCCGA CTGGGATGCG GTGATCGACA CCAACCTGAC
	CTCGCTGTTC

22201	AACGTCACCA AGCAGGTGAT CGACGGCATG GCCGACCGTG
	GCTGGGGCCG

22251	CATCGTCAAC ATCTCGTCGG TGAACGGGCA GAAGGGCCAG
	TTCGGCCAGA

22301	CCAACTACTC CACCGCCAAG GCCGGCCTGC ATGGCTTCAC
	CATGGCACTG

22351	GCGCAGGAAG TGGCGACCAA GGGCGTGACC GTCAACACGG
	TCTCTCCGGG

22401	CTATATCGCC ACCGACATGG TCAAGGCGAT CCGCCAGGAC
	GTGCTCGACA

22451	AGATCGTCGC GACGATCCCG GTCAAGCGCC TGGGCCTGCC
	GGAAGAGATC

22501	GCCTCGATCT GCGCCTGGTT GTCGTCGGAG GAGTCCGGTT
	TCTCGACCGG

22551	CGCCGACTTC TCGCTCAACG GCGGCCTGCA TATGGGCTGA
	GCGGCCGCTG

22601	AGTAATTCTG ATATTAGAGG GAGCATTAAT GTGTTGTTGT
	GATGTGGTTT

22651	ATATGGGGAA ATTAAATAAA TGATGTATGT ACCTCTTGCC
	TATGTAGGTT

22701	TGTGTGTTTT GTTTTGTTGT CTAGCTTTGG TTATTAAGTA
	GTAGGGACGT

22751	TCGTTCGTGT CTCAAAAAAA GGGGTACTAC CACTCTGTAG
	TGTATATGGA

22801	TGCTGGAAAT CAATGTGTTT TGTATTTGTT CACCTCCATT
	GTTGAATTCA

22851	ATGTCAAATG TGTTTTGCGT TGGTTATGTG TAAAATTACT
	ATCTTTCTCG

22901	TCCGATGATC AAAGTTTTAA GCAACAAAAC CAAGGGTGAA
	ATTTAAACTG

22951	TGCTTTGTTG AAGATTCTTT TATCATATTG AAAATCAAAT
	TACTAGCAGC

23001	AGATTTTACC TAGCATGAAA TTTTATCAAC AGTACAGCAC
	TCACTAACCA

23051	AGTTCCAAAC TAAGATGCGC CATTAACATC AGCCAATAGG
	CATTTTCAGC

23101	AAGGCGCGTA A

pMBXVT3

(SEQ ID NO: 8)

1	GGGGATCCGT ACGTAAGTAC GTACTCAAAA TGCCAACAAA
	TAAAAAAAAA

51	GTTGCTTTAA TAATGCCAAA ACAAATTAAT AAAACACTTA
	CAACACCGGA

101	TTTTTTTTAA TTAAAATGTG CCATTTAGGA TAAATAGTTA
	ATATTTTTAA

151	TAATTATTTA AAAAGCCGTA TCTACTAAAA TGATTTTTAT
	TTGGTTGAAA

201	ATATTAATAT GTTTAAATCA ACACAATCTA TCAAAATTAA
	ACTAAAAAAA

251	AAATAAGTGT ACGTGGTTAA CATTAGTACA GTAATATAAG
	AGGAAAATGA

301	GAAATTAAGA AATTGAAAGC GAGTCTAATT TTTAAATTAT
	GAACCTGCAT

351	ATATAAAAGG AAAGAAAGAA TCCAGGAAGA AAAGAAATGA
	AACCATGCAT

401	GGTCCCCTCG TCATCACGAG TTTCTGCCAT TTGCAATAGA
	AACACTGAAA

451	CACCTTTCTC TTTGTCACTT AATTGAGATG CCGAAGCCAC
	CTCACACCAT

501	GAACTTCATG AGGTGTAGCA CCCAAGGCTT CCATAGCCAT
	GCATACTGAA

551	GAATGTCTCA AGCTCAGCAC CCTACTTCTG TGACGTGTCC
	CTCATTCACC

601	TTCCTCTCTT CCCTATAAAT AACCACGCCT CAGGTTCTCC
	GCTTCACAAC

651	TCAAACATTC TCTCCATTGG TCCTTAAACA CTCATCAGTC
	ATCACCGCGG

701	CCGCGGAATT CATGGCTTCT ATGATATCCT CTTCCGCTGT
	GACAACAGTC

751	AGCCGTGCCT CTAGGGGGCA ATCCGCCGCA GTGGCTCCAT
	TCGGCGGCCT

801	CAAATCCATG ACTGGATTCC CAGTGAAGAA GGTCAACACT
	GACATTACTT

851	CCATTACAAG CAATGGTGGA AGAGTAAAGT GCATGCAGGT
	GTGGCCTCCA

901	ATTGGAAAGA AGAAGTTTGA GACTCTTTCC TATTTGCCAC
	CATTGACGAG

951	AGATTCTAGA GTGACTGACG TTGTCATCGT ATCCGCCGCC
	CGCACCGCGG

1001	TCGGCAAGTT TGGCGGCTCG CTGGCCAAGA TCCCGGCACC
	GGAACTGGGT

1051	GCCGTGGTCA TCAAGGCCGC GCTGGAGCGC GCCGGCGTCA
	AGCCGGAGCA

1101	GGTGAGCGAA GTCATCATGG GCCAGGTGCT GACCGCCGGT
	TCGGGCCAGA

1151	ACCCCGCACG CCAGGCCGCG ATCAAGGCCG GCCTGCCGGC
	GATGGTGCCG

1201	GCCATGACCA TCAACAAGGT GTGCGGCTCG GGCCTGAAGG
	CCGTGATGCT

1251	GGCCGCCAAC GCGATCATGG CGGGCGACGC CGAGATCGTG
	GTGGCCGGCG

1301	GCCAGGAAAA CATGAGCGCC GCCCCGCACG TGCTGCCGGG
	CTCGCGCGAT

1351	GGTTTCCGCA TGGGCGATGC CAAGCTGGTC GACACCATGA
	TCGTCGACGG

1401	CCTGTGGGAC GTGTACAACC AGTACCACAT GGGCATCACC
	GCCGAGAACG

1451	TGGCCAAGGA ATACGGCATC ACACGCGAGG CGCAGGATGA
	GTTCGCCGTC

1501	GGCTCGCAGA ACAAGGCCGA AGCCGCGCAG AAGGCCGGCA
	AGTTTGACGA

1551	AGAGATCGTC CCGGTGCTGA TCCCGCAGCG CAAGGGCGAC
	CCGGTGGCCT

1601	TCAAGACCGA CGAGTTCGTG CGCCAGGGCG CCACGCTGGA
	CAGCATGTCC

1651	GGCCTCAAGC CCGCCTTCGA CAAGGCCGGC ACGGTGACCG
	CGGCCAACGC

1701	CTCGGGCCTG AACGACGGCG CCGCCGCGGT GGTGGTGATG
	TCGGCGGCCA

1751	AGGCCAAGGA ACTGGGCCTG ACCCCGCTGG CCACGATCAA
	GAGCTATGCC

1801	AACGCCGGTG TCGATCCCAA GGTGATGGGC ATGGGCCCGG
	TGCCGGCCTC

1851	CAAGCGCGCC CTGTCGCGCG CCGAGTGGAC CCCGCAAGAC
	CTGGACCTGA

1901	TGGAGATCAA CGAGGCCTTT GCCGCGCAGG CGCTGGCGGT
	GCACCAGCAG

1951	ATGGGCTGGG ACACCTCCAA GGTCAATGTG AACGGCGGCG
	CCATCGCCAT

2001	CGGCCACCCG ATCGGCGCGT CGGGCTGCCG TATCCTGGTG
	ACGCTGCTGC

2051	ACGAGATGAA GCGCCGTGAC GCGAAGAAGG GCCTGGCCTC
	GCTGTGCATC

2101	GGCGGCGGCA TGGGCGTGGC GCTGGCAGTC GAGCGCAAAT
	AACTCGAGGC

2151	GGCCGCAGCC CTTTTTGTAT GTGCTACCCC ACTTTTGTCT
	TTTTGGCAAT

2201	AGTGCTAGCA ACCAATAAAT AATAATAATA ATAATGAATA
	AGAAAACAAA

2251	GGCTTTAGCT TGCCTTTTGT TCACTGTAAA ATAATAATGT
	AAGTACTCTC

2301	TATAATGAGT CACGAAACTT TTGCGGGAAT AAAAGGAGAA
	ATTCCAATGA

2351	GTTTTCTGTC AAATCTTCTT TTGTCTCTCT CTCTCTCTCT
	TTTTTTTTTT

2401	TCTTTCTTCT GAGCTTCTTG CAAAACAAAA GGCAAACAAT
	AACGATTGGT

2451	CCAATGATAG TTAGCTTGAT CGATGATATC TTTAGGAAGT
	GTTGGCAGGA

2501	CAGGACATGA TGTAGAAGAC TAAAATTGAA AGTATTGCAG
	ACCCAATAGT

2551	TGAAGATTAA CTTTAAGAAT GAAGACGTCT TATCAGGTTC
	TTCATGACTT

2601	AAGCTTCTGC AGGGAGTACT GTCCTCCGAG CGGAGTACTG
	TCCTCCGAGC

2651	GGAGTACTGT CCTCCGAGCG GAGTACTGTC CTCCGAGCGG
	AGTACTGTCC

2701	TCCGAGCGGA GACTCTAGTG CAAGACCCTT CCTCTATATA
	AGGAAGTTCA

2751	TTTCATTTGG AGAGGACACG CTGAAATCAC CAGTCTCTCT
	CTAAGCTAGC

2801	TTGGATCCTC GAGAAAATGG CTTCTATGAT ATCCTCTTCC
	GCTGTGACAA

2851	CAGTCAGCCG TGCCTCTAGG GGGCAATCCG CCGCAGTGGC
	TCCATTCGGC

2901	GGCCTCAAAT CCATGACTGG ATTCCCAGTG AAGAAGGTCA
	ACACTGACAT

2951	TACTTCCATT ACAAGCAATG GTGGAAGAGT AAAGTGCATG
	CAGGTGTGGC

3001	CTCCAATTGG AAAGAAGAAG TTTGAGACTC TTTCCTATTT
	GCCACCATTG

3051	ACGAGAGATT CTAGAGTGCT CTACCAATTG CATGAGTTCC
	AGCGCTCGAT

3101	CCTGCACCCG CTGACCGCGT GGGCCCAGGC GACCGCCAAG
	ACCTTCACCA

3151	ACCCCCTCAG CCCGCTCTCG CTGGTTCCCG GCGCACCCCG
	CCTGGCTGCC

3201	GGCTATGAAC TGCTGTACCG GCTCGGCAAG GAATACGAAA
	AGCCGGCATT

3251	CGACATCAAG TCGGTGCGCT CCAACGGGCG CGACATCCCC
	ATCGTCGAGC

3301	AGACCGTGCT TGAAAAGCCG TTCTGCAAGC TGGTGCGCTT
	CAAGCGCTAT

3351	GCCGACGACC CGGAGACCAT CAAGCTGCTC AAGGATGAGC
	CGGTGGTGCT

3401	GGTGGCCGCG CCGCTGTCGG GCCACCATGC CACGCTGCTG
	CGCGACACGG

3451	TGCGCACGCT GCTCCAGGAC CACAAGGTCT ACGTCACCGA
	CTGGATCGAC

3501	GCACGCATGG TGCCGGTCGA GGAAGGCGCG TTCCACCTGT
	CGGACTACAT

3551	CTACTACATC CAGGAGTTCA TCCGCCATAT CGGCGCCGAG
	AACCTGCATG

3601	TGATCTCGGT ATGCCAGCCC ACCGTGCCGG TGCTGGCCGC
	GATCTCGCTG

3651	ATGGCCTCGG CCGGCGAGAA GACGCCGCGC ACCATGACCA
	TGATGGGCGG

3701	CCCGATCGAC GCCCGCAAGA GCCCCACGGC GGTCAACTCG
	CTGGCGACCA

3751	ACAAGTCGTT CGAGTGGTTC GAGAACAACG TCATCTACAC
	CGTGCCGGCC

3801	AACTACCCCG GCCACGGCCG CCGCGTCTAC CCAGGCTTTT
	TGCAGCATGC

3851	CGGTTTCGTG GCGATGAACC CGGACCGGCA CCTTTCCTCG
	CACTATGACT

3901	TCTACCTGAG CCTGGTCGAG GGCGATGCGG ATGACGCCGA
	AGCCCACGTG

3951	CGCTTCTACG ACGAATACAA CGCGGTGCTC GACATGGCCG
	CCGAGTACTA

4001	CCTCGACACC ATCCGCGAGG TGTTCCAGGA GTTCCGCCTG
	GCCAACGGCA

4051	CCTGGGCCAT CGACGGCAAT CCGGTCCGGC CGCAGGACAT
	CAAGAGCACC

4101	GCGCTGATGA CCGTCGAGGG CGAACTGGAC GACATCTCGG
	GCGCGGGCCA

4151	GACCGCAGCG GCGCACGACC TGTGCGCCGG CATCCCGAAA
	ATCCGCAAGC

4201	AGCACCTGAA CGCGGCACAC TGCGGCCACT ACGGCATCTT
	CTCGGGCCGG

4251	CGCTGGCGCG AAGAGATATA CCCGCAGCTG CGCGACTTTA
	TCCGCAAGTA

4301	CCACCAGGCC TCGGCCACCA GGTAAGAGCT CGAATTGATC
	CTCTAGAGCT

4351	TTCGTTCGTA TCATCGGTTT CGACAACGTT CGTCAAGTTC
	AATGCATCAG

4401	TTTCATTGCG CACACACCAG AATCCTACTG AGTTCGAGTA
	TTATGGCATT

4451	GGGAAAACTG TTTTTCTTGT ACCATTTGTT GTGCTTGTAA
	TTTACTGTGT

4501	TTTTTATTCG GTTTTCGCTA TCGAACTGTG AAATGGAAAT
	GGATGGAGAA

4551	GAGTTAATGA ATGATATGGT CCTTTTGTTC ATTCTCAAAT
	TAATATTATT

4601	TGTTTTTTCT CTTATTTGTT GTGTGTTGAA TTTGAAATTA
	TAAGAGATAT

4651	GCAAACATTT TGTTTTGAGT AAAAATGTGT CAAATCGTGG
	CCTCTAATGA

4701	CCGAAGTTAA TATGAGGAGT AAAACACTTG TAGTTGTACC
	ATTATGCTTA

4751	TTCACTAGGC AACAAATATA TTTTCAGACC TAGAAAAGCT
	GCAAATGTTA

4801	CTGAATACAA GTATGTCCTC TTGTGTTTTA GACATTTATG
	AACTTTCCTT

4851	TATGTAATTT TCCAGAATCC TTGTCAGATT CTAATCATTG
	CTTTATAATT

4901	ATAGTTATAC TCATGGATTT GTAGTTGAGT ATGAAAATAT
	TTTTTAATGC

4951	ATTTTATGAC TTGCCAATTG ATTGACAACA TGCATCAGTC
	GAGGGAGTAC

5001	TGTCCTCCGA GCGGAGTACT GTCCTCCGAG CGGAGTACTG
	TCCTCCGAGC

5051	GGAGTACTGT CCTCCGAGCG GAGTACTGTC CTCCGAGCGG
	AGACTCTAGT

5101	GCAAGACCCT TCCTCTATAT AAGGAAGTTC ATTTCATTTG
	GAGAGGACAC

5151	GCTGAAATCA CCAGTCTCTC TCTAAGCTAG CTTGGATCCT
	CGAGAAAATG

5201	GCTTCTATGA TATCCTCTTC CGCTGTGACA ACAGTCAGCC
	GTGCCTCTAG

5251	GGGGCAATCC GCCGCAGTGG CTCCATTCGG CGGCCTCAAA
	TCCATGACTG

5301	GATTCCCAGT GAAGAAGGTC AACACTGACA TTACTTCCAT
	TACAAGCAAT

5351	GGTGGAAGAG TAAAGTGCAT GCAGGTGTGG CCTCCAATTG
	GAAAGAAGAA

5401	GTTTGAGACT CTTTCCTATT TGCCACCATT GACGAGAGAT
	TCTAGAGTGC

5451	TCAAAGGAAA AGTCGCAGTC GTCACCGGTT CCACCAGCGG
	GATCGGCCTG

5501	GGTATCGCCA CCGCGCTGGC CGCGCAGGGC GCCGATATCG
	TCCTGAACGG

5551	CTTCGGCGAC GCCGCCGAGA TCGAAAAGGT GCGCGCCGGC
	CTGGCCGCCC

5601	AGCATGGCGT CAAGGTGCTG TACGACGGCG CCGACCTGTC
	CAAGGGCGAG

5651	GCCGTGCGCG GCCTGGTGGA CAACGCGGTG CGCCAGATGG
	GCCGCATCGA

5701	CATCCTGGTC AACAACGCCG GCATCCAGCA CACCGCGCTG
	ATCGAGGACT

5751	TTCCCACCGA AAAATGGGAC GCCATCCTGG CGCTGAACCT
	GTCGGCCGTG

5801	TTCCACGGCA CCGCCGCCGC GCTGCCGCAC ATGAAGAAGC
	AGGGCTTCGG

5851	CCGCATCATC AACATCGCCT CGGCGCACGG CCTGGTGGCC
	TCGGCCAACA

5901	AGTCGGCCTA CGTCGCCGCC AAGCACGGCG TGGTGGGCTT
	CACCAAGGTG

5951	ACCGCGCTGG AAACCGCCGG CCAGGGCATC ACCGCCAACG
	CCATCTGCCC

6001	AGGCTGGGTG CGCACTCCGC TGGTCGAAAA GCAGATATCG
	GCGCTGGCCG

6051	AAAAGAACGG CGTGGACCAG GAAACCGCCG CGCGCGAACT
	GCTCAGCGAA

6101	AAGCAGCCGT CGCTGCAATT CGTCACGCCC GAACAACTGG
	GCGGCACGGC

6151	CGTCTTCCTG GCCTCCGATG CCGCCGCGCA AATCACCGGC
	ACGACCGTCT

6201	CCGTCGATGG CGGCTGGACG GCGCGCTGAG AGCTCGAATT
	GATCCTCTAG

6251	AGCTTTCGTT CGTATCATCG GTTTCGACAA CGTTCGTCAA
	GTTCAATGCA

6301	TCAGTTTCAT TGCGCACACA CCAGAATCCT ACTGAGTTCG
	AGTATTATGG

6351	CATTGGGAAA ACTGTTTTTC TTGTACCATT TGTTGTGCTT
	GTAATTTACT

6401	GTGTTTTTTA TTCGGTTTTC GCTATCGAAC TGTGAAATGG
	AAATGGATGG

6451	AGAAGAGTTA ATGAATGATA TGGTCCTTTT GTTCATTCTC
	AAATTAATAT

6501	TATTTGTTTT TTCTCTTATT TGTTGTGTGT TGAATTTGAA
	ATTATAAGAG

6551	ATATGCAAAC ATTTTGTTTT GAGTAAAAAT GTGTCAAATC
	GTGGCCTCTA

6601	ATGACCGAAG TTAATATGAG GAGTAAAACA CTTGTAGTTG
	TACCATTATG

6651	CTTATTCACT AGGCAACAAA TATATTTTCA GACCTAGAAA
	AGCTGCAAAT

6701	GTTACTGAAT ACAAGTATGT CCTCTTGTGT TTTAGACATT
	TATGAACTTT

6751	CCTTTATGTA ATTTTCCAGA ATCCTTGTCA GATTCTAATC
	ATTGCTTTAT

6801	AATTATAGTT ATACTCATGG ATTTGTAGTT GAGTATGAAA
	ATATTTTTTA

6851	ATGCATTTTA TGACTTGCCA ATTGATTGAC AACATGCATC
	AACTAGTAGA

6901	AGGTAATTAT CCAAGATGTA GCATCAAGAA TCCAATGTTT
	ACGGGAAAAA

6951	CTATGGAAGT ATTATGTGAG CTCAGCAAGA AGCAGATCAA
	TATGCGGCAC

7001	ATATGCAACC TATGTTCAAA AATGAAGAAT GTACAGATAC
	AAGATCCTAT

7051	ACTGCCAGAA TACGAAGAAG AATACGTAGA AATTGAAAAA
	GAAGAACCAG

7101	GCGAAGAAAA GAATCTTGAA GACGTAAGCA CTGACGACAA
	CAATGAAAAG

7151	AAGAAGATAA GGTCGGTGAT TGTGAAAGAG ACATAGAGGA
	CACATGTAAG

7201	GTGGAAAATG TAAGGGCGGA AAGTAACCTT ATCACAAAGG
	AATCTTATCC

7251	CCCACTACTT ATCCTTTTAT ATTTTTCCGT GTCATTTTTG
	CCCTTGAGTT

7301	TTCCTATATA AGGAACCAAG TTCGGCATTT GTGAAAACAA
	GAAAAAATTG

7351	GTGTAAGCTA TTTTCTTTGA AGTACTGAGG ATACAACTTC
	AGAGAAATTT

7401	GTAAGAAAGT GGATCGAAAC CATGGCCTCC TCCGAGAACG
	TCATCACCGA

7451	GTTCATGCGC TTCAAGGTGC GCATGGAGGG CACCGTGAAC
	GGCCACGAGT

7501	TCGAGATCGA GGGCGAGGGC GAGGGCCGCC CCTACGAGGG
	CCACAACACC

7551	GTGAAGCTGA AGGTGACCAA GGGCGGCCCC CTGCCCTTCG
	CCTGGGACAT

7601	CCTGTCCCCC CAGTTCCAGT ACGGCTCCAA GGTGTACGTG
	AAGCACCCCG

7651	CCGACATCCC CGACTACAAG AAGCTGTCCT TCCCCGAGGG
	CTTCAAGTGG

7701	GAGCGCGTGA TGAACTTCGA GGACGGCGGC GTGGCGACCG
	TGACCCAGGA

7751	CTCCTCCCTG CAGGACGGCT GCTTCATCTA CAAGGTGAAG
	TTCATCGGCG

7801	TGAACTTCCC CTCCGACGGC CCCGTGATGC AGAAGAAGAC
	CATGGGCTGG

7851	GAGGCCTCCA CCGAGCGCCT GTACCCCCGC GACGGCGTGC
	TGAAGGGCGA

7901	GACCCACAAG GCCCTGAAGC TGAAGGACGG CGGCCACTAC
	CTGGTGGAGT

7951	TCAAGTCCAT CTACATGGCC AAGAAGCCCG TGCAGCTGCC
	CGGCTACTAC

8001	TACGTGGACG CCAAGCTGGA CATCACCTCC CACAACGAGG
	ACTACACCAT

8051	CGTGGAGCAG TACGAGCGCA CCGAGGGCCG CCACCACCTG
	TTCCTGGTAC

8101	CAATGAGCTC TGTCCAACAG TCTCAGGGTT AATGTCTATG
	TATCTTAAAT

8151	AATGTTGTCG GCGATCGTTC AAACATTTGG CAATAAAGTT
	TCTTAAGATT

8201	GAATCCTGTT GCCGGTCTTG CGATGATTAT CATATAATTT
	CTGTTGAATT

8251	ACGTTAAGCA TGTAATAATT AACATGTAAT GCATGACGTT
	ATTTATGAGA

8301	TGGGTTTTTA TGATTAGAGT CCCGCAATTA TACATTTAAT
	ACGCGATAGA

8351	AAACAAAATA TAGCGCGCAA ACTAGGATAA ATTATCGCGC
	GCGGTGTCAT

8401	CTATGTTACT AGATCGGGAA TTAAACTATC AGTGTTTGAC
	AGGATATATT

8451	GGCGGGTAAA CCTAAGAGAA AAGAGCGTTT ATTAGAATAA
	CGGATATTTA

8501	AAAGGGCGTG AAAAGGTTTA TCCGTTCGTC CATTTGTATG
	TGCATGCCAA

8551	CCACAGGGTT CCCCTCGGGA TCAAAGTACT TTGATCCAAC
	CCCTCCGCTG

8601	CTATAGTGCA GTCGGCTTCT GACGTTCAGT GCAGCCGTCT
	TCTGAAAACG

8651	ACATGTCGCA CAAGTCCTAA GTTACGCGAC AGGCTGCCGC
	CCTGCCCTTT

8701	TCCTGGCGTT TTCTTGTCGC GTGTTTTAGT CGCATAAAGT
	AGAATACTTG

8751	CGACTAGAAC CGGAGACATT ACGCCATGAA CAAGAGCGCC
	GCCGCTGGCC

8801	TGCTGGGCTA TGCCCGCGTC AGCACCGACG ACCAGGACTT
	GACCAACCAA

8851	CGGGCCGAAC TGCACGCGGC CGGCTGCACC AAGCTGTTTT
	CCGAGAAGAT

8901	CACCGGCACC AGGCGCGACC GCCCGGAGCT GGCCAGGATG
	CTTGACCACC

8951	TACGCCCTGG CGACGTTGTG ACAGTGACCA GGCTAGACCG
	CCTGGCCCGC

9001	AGCACCCGCG ACCTACTGGA CATTGCCGAG CGCATCCAGG
	AGGCCGGCGC

9051	GGGCCTGCGT AGCCTGGCAG AGCCGTGGGC CGACACCACC
	ACGCCGGCCG

9101	GCCGCATGGT GTTGACCGTG TTCGCCGGCA TTGCCGAGTT
	CGAGCGTTCC

9151	CTAATCATCG ACCGCACCCG GAGCGGGCGC GAGGCCGCCA
	AGGCCCGAGG

9201	CGTGAAGTTT GGCCCCCGCC CTACCCTCAC CCCGGCACAG
	ATCGCGCACG

9251	CGCGCGAGCT GATCGACCAG GAAGGCCGCA CCGTGAAAGA
	GGCGGCTGCA

9301	CTGCTTGGCG TGCATCGCTC GACCCTGTAC CGCGCACTTG
	AGCGCAGCGA

9351	GGAAGTGACG CCCACCGAGG CCAGGCGGCG CGGTGCCTTC
	CGTGAGGACG

9401	CATTGACCGA GGCCGACGCC CTGGCGGCCG CCGAGAATGA
	ACGCCAAGAG

9451	GAACAAGCAT GAAACCGCAC CAGGACGGCC AGGACGAACC
	GTTTTTCATT

9501	ACCGAAGAGA TCGAGGCGGA GATGATCGCG GCCGGGTACG
	TGTTCGAGCC

9551	GCCCGCGCAC GTCTCAACCG TGCGGCTGCA TGAAATCCTG
	GCCGGTTTGT

9601	CTGATGCCAA GCTGGCGGCC TGGCCGGCCA GCTTGGCCGC
	TGAAGAAACC

9651	GAGCGCCGCC GTCTAAAAAG GTGATGTGTA TTTGAGTAAA
	ACAGCTTGCG

9701	TCATGCGGTC GCTGCGTATA TGATGCGATG AGTAAATAAA
	CAAATACGCA

9751	AGGGGAACGC ATGAAGGTTA TCGCTGTACT TAACCAGAAA
	GGCGGGTCAG

9801	GCAAGACGAC CATCGCAACC CATCTAGCCC GCGCCCTGCA
	ACTCGCCGGG

9851	GCCGATGTTC TGTTAGTCGA TTCCGATCCC CAGGGCAGTG
	CCCGCGATTG

9901	GGCGGCCGTG CGGGAAGATC AACCGCTAAC CGTTGTCGGC
	ATCGACCGCC

9951	CGACGATTGA CCGCGACGTG AAGGCCATCG GCCGGCGCGA
	CTTCGTAGTG

10001	ATCGACGGAG CGCCCCAGGC GGCGGACTTG GCTGTGTCCG
	CGATCAAGGC

10051	AGCCGACTTC GTGCTGATTC CGGTGCAGCC AAGCCCTTAC
	GACATATGGG

10101	CCACCGCCGA CCTGGTGGAG CTGGTTAAGC AGCGCATTGA
	GGTCACGGAT

10151	GGAAGGCTAC AAGCGGCCTT TGTCGTGTCG CGGGCGATCA
	AAGGCACGCG

10201	CATCGGCGGT GAGGTTGCCG AGGCGCTGGC CGGGTACGAG
	CTGCCCATTC

10251	TTGAGTCCCG TATCACGCAG CGCGTGAGCT ACCCAGGCAC
	TGCCGCCGCC

10301	GGCACAACCG TTCTTGAATC AGAACCCGAG GGCGACGCTG
	CCCGCGAGGT

10351	CCAGGCGCTG GCCGCTGAAA TTAAATCAAA ACTCATTTGA
	GTTAATGAGG

10401	TAAAGAGAAA ATGAGCAAAA GCACAAACAC GCTAAGTGCC
	GGCCGTCCGA

10451	GCGCACGCAG CAGCAAGGCT GCAACGTTGG CCAGCCTGGC
	AGACACGCCA

10501	GCCATGAAGC GGGTCAACTT TCAGTTGCCG GCGGAGGATC
	ACACCAAGCT

10551	GAAGATGTAC GCGGTACGCC AAGGCAAGAC CATTACCGAG
	CTGCTATCTG

10601	AATACATCGC GCAGCTACCA GAGTAAATGA GCAAATGAAT
	AAATGAGTAG

10651	ATGAATTTTA GCGGCTAAAG GAGGCGGCAT GGAAAATCAA
	GAACAACCAG

10701	GCACCGACGC CGTGGAATGC CCCATGTGTG GAGGAACGGG
	CGGTTGGCCA

10751	GGCGTAAGCG GCTGGGTTGT CTGCCGGCCC TGCAATGGCA
	CTGGAACCCC

10801	CAAGCCCGAG GAATCGGCGT GACGGTCGCA AACCATCCGG
	CCCGGTACAA

10851	ATCGGCGCGG CGCTGGGTGA TGACCTGGTG GAGAAGTTGA
	AGGCCGCGCA

10901	GGCCGCCCAG CGGCAACGCA TCGAGGCAGA AGCACGCCCC
	GGTGAATCGT

10951	GGCAAGCGGC CGCTGATCGA ATCCGCAAAG AATCCCGGCA
	ACCGCCGGCA

11001	GCCGGTGCGC CGTCGATTAG GAAGCCGCCC AAGGGCGACG
	AGCAACCAGA

11051	TTTTTTCGTT CCGATGCTCT ATGACGTGGG CACCCGCGAT
	AGTCGCAGCA

11101	TCATGGACGT GGCCGTTTTC CGTCTGTCGA AGCGTGACCG
	ACGAGCTGGC

11151	GAGGTGATCC GCTACGAGCT TCCAGACGGG CACGTAGAGG
	TTTCCGCAGG

11201	GCCGGCCGGC ATGGCCAGTG TGTGGGATTA CGACCTGGTA
	CTGATGGCGG

11251	TTTCCCATCT AACCGAATCC ATGAACCGAT ACCGGGAAGG
	GAAGGGAGAC

11301	AAGCCCGGCC GCGTGTTCCG TCCACACGTT GCGGACGTAC
	TCAAGTTCTG

11351	CCGGCGAGCC GATGGCGGAA AGCAGAAAGA CGACCTGGTA
	GAAACCTGCA

11401	TTCGGTTAAA CACCACGCAC GTTGCCATGC AGCGTACGAA
	GAAGGCCAAG

11451	AACGGCCGCC TGGTGACGGT ATCCGAGGGT GAAGCCTTGA
	TTAGCCGCTA

11501	CAAGATCGTA AAGAGCGAAA CCGGGCGGCC GGAGTACATC
	GAGATCGAGC

11551	TAGCTGATTG GATGTACCGC GAGATCACAG AAGGCAAGAA
	CCCGGACGTG

11601	CTGACGGTTC ACCCCGATTA CTTTTTGATC GATCCCGGCA
	TCGGCCGTTT

11651	TCTCTACCGC CTGGCACGCC GCGCCGCAGG CAAGGCAGAA
	GCCAGATGGT

11701	TGTTCAAGAC GATCTACGAA CGCAGTGGCA GCGCCGGAGA
	GTTCAAGAAG

11751	TTCTGTTTCA CCGTGCGCAA GCTGATCGGG TCAAATGACC
	TGCCGGAGTA

11801	CGATTTGAAG GAGGAGGCGG GGCAGGCTGG CCCGATCGTA
	GTCATGCGCT

11851	ACCGCAACCT GATCGAGGGC GAAGCATCCG CCGGTTCCTA
	ATGTACGGAG

11901	CAGATGCTAG GGCAAATTGC CCTAGCAGGG GAAAAAGGTC
	GAAAAGGTCT

11951	CTTTCCTGTG GATAGCACGT ACATTGGGAA CCCAAAGCCG
	TACATTGGGA

12001	ACCGGAACCC GTACATTGGG AACCCAAAGC CGTACATTGG
	GAACCGGTCA

12051	CACATGTAAG TGACTGATAT AAAAGAGAAA AAAGGCGATT
	TTTCCGCCTA

12101	AAACTCTTTA AAACTTATTA AAACTCTTAA AACCCGCCTG
	GCCTGTGCAT

12151	AACTGTCTGG CCAGCGCACA GCCGAAGAGC TGCAAAAAGC
	GCCTACCCTT

12201	CGGTCGCTGC GCTCCCTACG CCCCGCCGCT TCGCGTCGGC
	CTATCGCGGC

12251	CGCTGGCCGC TCAAAAATGG CTGGCCTACG GCCAGGCAAT
	CTACCAGGGC

12301	GCGGACAAGC CGCGCCGTCG CCACTCGACC GCCGGCGCCC
	ACATCAAGGC

12351	ACCCTGCCTC GCGCGTTTCG GTGATGACGG TGAAAACCTC
	TGACACATGC

12401	AGCTCCCGGA GACGGTCACA GCTTGTCTGT AAGCGGATGC
	CGGGAGCAGA

12451	CAAGCCCGTC AGGGCGCGTC AGCGGGTGTT GGCGGGTGTC
	GGGGCGCAGC

12501	CATGACCCAG TCACGTAGCG ATAGCGGAGT GTATACTGGC
	TTAACTATGC

12551	GGCATCAGAG CAGATTGTAC TGAGAGTGCA CCATATGCGG
	TGTGAAATAC

12601	CGCACAGATG CGTAAGGAGA AAATACCGCA TCAGGCGCTC
	TTCCGCTTCC

12651	TCGCTCACTG ACTCGCTGCG CTCGGTCGTT CGGCTGCGGC
	GAGCGGTATC

12701	AGCTCACTCA AAGGCGGTAA TACGGTTATC CACAGAATCA
	GGGGATAACG

12751	CAGGAAAGAA CATGTGAGCA AAAGGCCAGC AAAAGGCCAG
	GAACCGTAAA

12801	AAGGCCGCGT TGCTGGCGTT TTTCCATAGG CTCCGCCCCC
	CTGACGAGCA

12851	TCACAAAAAT CGACGCTCAA GTCAGAGGTG GCGAAACCCG
	ACAGGACTAT

12901	AAAGATACCA GGCGTTTCCC CCTGGAAGCT CCCTCGTGCG
	CTCTCCTGTT

12951	CCGACCCTGC CGCTTACCGG ATACCTGTCC GCCTTTCTCC
	CTTCGGGAAG

13001	CGTGGCGCTT TCTCATAGCT CACGCTGTAG GTATCTCAGT
	TCGGTGTAGG

13051	TCGTTCGCTC CAAGCTGGGC TGTGTGCACG AACCCCCCGT
	TCAGCCCGAC

13101	CGCTGCGCCT TATCCGGTAA CTATCGTCTT GAGTCCAACC
	CGGTAAGACA

13151	CGACTTATCG CCACTGGCAG CAGCCACTGG TAACAGGATT
	AGCAGAGCGA

13201	GGTATGTAGG CGGTGCTACA GAGTTCTTGA AGTGGTGGCC
	TAACTACGGC

13251	TACACTAGAA GGACAGTATT TGGTATCTGC GCTCTGCTGA
	AGCCAGTTAC

13301	CTTCGGAAAA AGAGTTGGTA GCTCTTGATC CGGCAAACAA
	ACCACCGCTG

13351	GTAGCGGTGG TTTTTTTGTT TGCAAGCAGC AGATTACGCG
	CAGAAAAAAA

13401	GGATCTCAAG AAGATCCTTT GATCTTTTCT ACGGGGTCTG
	ACGCTCAGTG

13451	GAACGAAAAC TCACGTTAAG GGATTTTGGT CATGCATTCT
	AGGTACTAAA

13501	ACAATTCATC CAGTAAAATA TAATATTTTA TTTTCTCCCA
	ATCAGGCTTG

13551	ATCCCCAGTA AGTCAAAAAA TAGCTCGACA TACTGTTCTT
	CCCCGATATC

13601	CTCCCTGATC GACCGGACGC AGAAGGCAAT GTCATACCAC
	TTGTCCGCCC

13651	TGCCGCTTCT CCCAAGATCA ATAAAGCCAC TTACTTTGCC
	ATCTTTCACA

13701	AAGATGTTGC TGTCTCCCAG GTCGCCGTGG GAAAAGACAA
	GTTCCTCTTC

13751	GGGCTTTTCC GTCTTTAAAA AATCATACAG CTCGCGCGGA
	TCTTTAAATG

13801	GAGTGTCTTC TTCCCAGTTT TCGCAATCCA CATCGGCCAG
	ATCGTTATTC

13851	AGTAAGTAAT CCAATTCGGC TAAGCGGCTG TCTAAGCTAT
	TCGTATAGGG

13901	ACAATCCGAT ATGTCGATGG AGTGAAAGAG CCTGATGCAC
	TCCGCATACA

13951	GCTCGATAAT CTTTTCAGGG CTTTGTTCAT CTTCATACTC
	TTCCGAGCAA

14001	AGGACGCCAT CGGCCTCACT CATGAGCAGA TTGCTCCAGC
	CATCATGCCG

14051	TTCAAAGTGC AGGACCTTTG GAACAGGCAG CTTTCCTTCC
	AGCCATAGCA

14101	TCATGTCCTT TTCCCGTTCC ACATCATAGG TGGTCCCTTT
	ATACCGGCTG

14151	TCCGTCATTT TTAAATATAG GTTTTCATTT TCTCCCACCA
	GCTTATATAC

14201	CTTAGCAGGA GACATTCCTT CCGTATCTTT TACGCAGCGG
	TATTTTTCGA

14251	TCAGTTTTTT CAATTCCGGT GATATTCTCA TTTTAGCCAT
	TTATTATTTC

14301	CTTCCTCTTT TCTACAGTAT TTAAAGATAC CCCAAGAAGC
	TAATTATAAC

14351	AAGACGAACT CCAATTCACT GTTCCTTGCA TTCTAAAACC
	TTAAATACCA

14401	GAAAACAGCT TTTTCAAAGT TGTTTTCAAA GTTGGCGTAT
	AACATAGTAT

14451	CGACGGAGCC GATTTTGAAA CCGCGGTGAT CACAGGCAGC
	AACGCTCTGT

14501	CATCGTTACA ATCAACATGC TACCCTCCGC GAGATCATCC
	GTGTTTCAAA

14551	CCCGGCAGCT TAGTTGCCGT TCTTCCGAAT AGCATCGGTA
	ACATGAGCAA

14601	AGTCTGCCGC CTTACAACGG CTCTCCCGCT GACGCCGTCC
	CGGACTGATG

14651	GGCTGCCTGT ATCGAGTGGT GATTTTGTGC CGAGCTGCCG
	GTCGGGGAGC

14701	TGTTGGCTGG CTGGTGGCAG GATATATTGT GGTGTAAACA
	AATTGACGCT

14751	TAGACAACTT AATAACACAT TGCGGACGTT TTTAATGTAC
	TGAATTAACG

14801	CCGAATTAAT TCCTAGTCCA ATACTCAACT TCAAGGAATC
	TCACCCATGC

14851	GCGCCGGCGG GGAACCGGAG TTCCCTTCAG TGAACGTTAT
	TAGTTCGCCG

14901	CTCGGTGTGT CGTAGATACT AGCCCCTGGG GCCTTTTGAA
	ATTTGAATAA

14951	GATTTATGTA ATCAGTCTTT TAGGTTTGAC CGGTTCTGCC
	GCTTTTTTTA

15001	AAATTGGATT TGTAATAATA AAACGCAATT GTTTGTTATT
	GTGGCGCTCT

15051	ATCATAGATG TCGCTATAAA CCTATTCAGC ACAATATATT
	GTTTTCATTT

15101	TAATATTGTA CATATAAGTA GTAGGGTACA ATCAGTAAAT
	TGAACGGAGA

15151	ATATTATTCA TAAAAATACG ATAGTAACGG GTGATATATT
	CATTCATTAG

15201	AATGAACCGA AACCGGCGGT AAGGATCTGA GCTACACATG
	CTCAGGTTTT

15251	TTACAACGTG CACAACAGAA TTGAAAGCAA ATATCATGCG
	ATCATAGGCG

15301	TCTCGCATAT CTCATTAAAG CAGCTGGAAG ATTTGATTCT
	AGATTAGAGA

15351	TTCGTGGGGG ACTCGAGATA GGCGGCGGTT GGGTGTGCGA
	CATGTCCTGC

15401	CACATCCCAG ATCTCCTCGA GGAAAGGCGG CAGCTTTCTG
	TTCTTGAGCT

15451	TGAGGGAGAT GCACATGTTG GAGTTTTGCA TGCCGAGCGT
	GCGTAGCTCA

15501	GAGAGGATTG AGAGGATCTT GCCGTATATG ACGGACGAAC
	GCGCCGACCC

15551	GCTCAGCTGG TTCAGGATAT AGATGCGGAG CGTATTCAGG
	TAGTACCGCT

15601	GGATTTCTTC CACCAGTTGC GGCTGCTCCA ACCCTGGCCG
	GTCAGAAAAG

15651	ATGACGACAG CCGTGAGCAG CGCGTAATGG ATGTTGTCCA
	ACGCCATAGA

15701	GTACATGCAC CGGCAGAAGT GCAGTAGATC CTCGATGACT
	TCGGCCATGC

15751	CAGCCTTGCG GTAGTTGTCG CGAGTGTACG CTTGGTTGTT
	CGGGAACAGA

15801	ATACTGTCTG AGGCCGCATC GTACTGCTGC GCGACTCGGA
	GCATCATTAC

15851	CTCACTTGAG CAAGCCTTAA GCAGCGTAAT TTGATCAGGC
	TGCGAGATCT

15901	TGGCGAACCC TGGCAATCCC TTCGCGAACT CCACGATAAG
	TTGGACCGTG

15951	AGGATAGTCA TCTCTACGAT CTGGCGGAAG GGAGTGTCAG
	ACTCTTCGTT

16001	TTCATCGTCC GCTTGCTGCC ACGTCTGCGT AATCCTCTTC
	AAATCTTCAT

16051	CAGAAGGCTG CTCGTACCCG TCCTGGTACC AGATGAGCCT
	GGCGATAAGG

16101	AACTGCTGGT TGGCTGTCAA CTGGGGGATG TTTTTCTGCC
	GGTTTGTCTC

16151	CAACAGCTTG TCGGAGAGAA ACCTTGGAAC CACTTCGTGA
	ATCCTTGCTG

16201	CTTCAGGAGG TGGAGGTTCA CACTGCATAA TGGGCGGCAT
	GTGGTCGTCC

16251	ACCGTCGTCG TGCTGACAGG CAGTTTGTCC TTCTCCTTCT
	GTGCTTTCTT

16301	CTCTTTCCGC TTCATGGCGC ACTGAGTCTC GGGTACTACG
	CACTCAGGCC

16351	TGATCCCCGG GAATTCCGGC GATACAGTCA ACTGTCTTTG
	ACCTTTGTTA

16401	CTACTCTCTT CCGATGATGA TGTCGCACTT ATTCTATGCT
	GTCTCAATGT

16451	TAGAGGCATA TCAGTCTCCA CTGAAGCCAA TCTATCTGTG
	ACGGCATCTT

16501	TATTCACATT ATCTTGTACA AATAATCCTG TTAACAATGC
	TTTTATATCC

16551	TGTAAAGAAT CCATTTTCAA AATCATGTCA AGGTCTTCTC
	GAGGAAAAAT

16601	CAGTAGAAAT AGCTGTTCCA GTCTTTCTAG CCTTGATTCC
	ACTTCTGTCA

16651	GATGTGCCCT AGTCAGCGGA GACCTTTTGG TTTTGGGAGA
	GTAGCGACAC

16701	TCCCAGTTGT TCTTCAGACA CTTGGCGCAC TTCGGTTTTT
	CTTTGGAGCA

16751	CTTGAGCTTT TTAAGTCGGC AAATATCGCA TGCTTGTTCG
	ATAGAAGACA

16801	GTAGCTTCAG TCGACGGATC CCTGGCGATC CCGGACCCGG
	GGAATCCCCG

16851	TCCCCCAACA TGTCCAGATC GAAATCGTCT AGCGCGTCGG
	CATGCGCCAT

16901	CGCCACGTCC TCGCCGTCTA AGTGGAGCTC GTCCCCCAGG
	CTGACATCGG

16951	TCGGGGGGGC CGTCGAGATC CCCGGGAATT CATCTACCTT
	TCTCTTCTTT

17001	TTTGGGCATG CTTGTTCGAT AGAAGACAGT AGCTTCATCT
	TTCAGGAGGC

17051	TTGCTTCAAG CTGGCTAGAC TCGAGAGATG AGAGATTTCG
	ATTCCGATTT

17101	TGATTTCGAT TCCGATTTTG ATTTCGATTG ATCTCTTCCT
	TCTGATTTGT

17151	GTTCCTTATA TAAGGAAATT CTTGTGGGAT TAGACGTCAT
	GGCTTACGTC

17201	ATTTCCTTCG TCCTGTTGCT CACTGATTGA GCTGTGAGTG
	GAGGGACCAC

17251	TGGAAGATGC TTCACTAATT TTCTTAGTGG AGGGACCGGC
	TTCACATGCT

17301	TCACACAAGT GGCTGTCGGG CATCATCTTT TTTAGCTTTT
	GACAAAGCAA

17351	TGTTTTAGTG GTGGCTCCCA CTCTTATCTT CAACATTATT
	ATCTTATCTT

17401	CAAAGGACGA TAAGATGTTG ATGTCTGTGG ACGAAGTTGG
	GATTAGACGT

17451	CATGGCTTAC GTCATTTCCT TCGTCCTGTT GCTCACTGAT
	TGAGCTGTGA

17501	GTGGAGGGAC CACTGGAAGA TGCTTCACTA ATTTTCTTAG
	TGGAGGGACC

17551	GGCTTCACAT GCTTCACACA AGTGGCTGTC GGGCATCATC
	TTTTTTAGCT

17601	TTTGACAAAG CAATGTTTTA GTGGTGGCTC CCACTCTTAT
	CTTCAACATT

17651	ATTATCTTAT CTTCAAAGGA CGATAAGATG TTGATGTCTG
	TGGACGAAGT

17701	TGACGAATTC CTGCAGGCGG CCGCCATATG CATCCTAGGC
	CACCATGTTG

17751	GGCCCGGGGC GCGCCGTACG TAGTGTTTAT CTTTGTTGCT
	TTTCTGAACA

17801	ATTTATTTAC TATGTAAATA TATTATCAAT GTTTAATCTA
	TTTTAATTTG

17851	CACATGAATT TTCATTTTAT TTTTACTTTA CAAAACAAAT
	AAATATATAT

17901	GCAAAAAAAT TTACAAACGA TGCACGGGTT ACAAACTAAT
	TTCATTAAAT

17951	GCTAATGCAG ATTTTGTGAA GTAAAACTCC AATTATGATG
	AAAAATACCA

18001	CCAACACCAC CTGCGAAACT GTATCCCAAC TGTCCTTAAT
	AAAAATGTTA

18051	AAAAGTATAT TATTCTCATT TGTCTGTCAT AATTTATGTA
	CCCCACTTTA

18101	ATTTTTCTGA TGTACTAAAC CGAGGGCAAA CTGAAACCTG
	TTCCTCATGC

18151	AAAGCCCCTA CTCACCATGT ATCATGTACG TGTCATCACC
	CAACAACTCC

18201	ACTTTTGCTA TATAACAACA CCCCCGTCAC ACTCTCCCTC
	TCTAACACAC

18251	ACCCCACTAA CAATTCCTTC ACTTGCAGCA CTGTTGCATC
	ATCATCTTCA

18301	TTGCAAAACC CTAAACTTCA CCTTCAACCG CGGCCGCATG
	GCTTCTATGA

18351	TATCCTCTTC CGCTGTGACA ACAGTCAGCC GTGCCTCTAG
	GGGGCAATCC

18401	GCCGCAGTGG CTCCATTCGG CGGCCTCAAA TCCATGACTG
	GATTCCCAGT

18451	GAAGAAGGTC AACACTGACA TTACTTCCAT TACAAGCAAT
	GGTGGAAGAG

18501	TAAAGTGCAT GCAGGTGTGG CCTCCAATTG GAAAGAAGAA
	GTTTGAGACT

18551	CTTTCCTATT TGCCACCATT GACGAGAGAT TCTAGAGTGA
	GTAACAAGAA

18601	CAACGATGAG CTGCAGTGGC AATCCTGGTT CAGCAAGGCG
	CCCACCACCG

18651	AGGCGAACCC GATGGCCACC ATGTTGCAGG ATATCGGCGT
	TGCGCTCAAA

18701	CCGGAAGCGA TGGAGCAGCT GAAAAACGAT TATCTGCGTG
	ACTTCACCGC

18751	GTTGTGGCAG GATTTTTTGG CTGGCAAGGC GCCAGCCGTC
	AGCGACCGCC

18801	GCTTCAGCTC GGCAGCCTGG CAGGGCAATC CGATGTCGGC
	CTTCAATGCC

18851	GCATCTTACC TGCTCAACGC CAAATTCCTC AGTGCCATGG
	TGGAGGCGGT

18901	GGACACCGCA CCCCAGCAAA AGCAGAAAAT ACGCTTTGCC
	GTGCAGCAGG

18951	TGATTGATGC CATGTCGCCC GCGAACTTCC TCGCCACCAA
	CCCGGAAGCG

19001	CAGCAAAAAC TGATTGAAAC CAAGGGCGAG AGCCTGACGC
	GTGGCCTGGT

19051	CAATATGCTG GGCGATATCA ACAAGGGCCA TATCTCGCTG
	TCGGACGAAT

19101	CGGCCTTTGA AGTGGGCCGC AACCTGGCCA TTACCCCGGG
	CACCGTGATT

19151	TACGAAAATC CGCTGTTCCA GCTGATCCAG TACACGCCGA
	CCACGCCGAC

19201	GGTCAGCCAG CGCCCGCTGT TGATGGTGCC GCCGTGCATC
	AACAAGTTCT

19251	ACATCCTCGA CCTGCAACCG GAAAATTCGC TGGTGCGCTA
	CGCGGTGGAG

19301	CAGGGCAACA CCGTGTTCCT GATCTCGTGG AGCAATCCGG
	ACAAGTCGCT

19351	GGCCGGCACC ACCTGGGACG ACTACGTGGA GCAGGGCGTG
	ATCGAAGCGA

19401	TCCGCATCGT CCAGGACGTC AGCGGCCAGG ACAAGCTGAA
	CATGTTCGGC

19451	TTCTGCGTGG GCGGCACCAT CGTTGCCACC GCACTGGCGG
	TACTGGCGGC

19501	GCGTGGCCAG CACCCGGCGG CCAGCCTGAC CCTGCTGACC
	ACCTTCCTCG

19551	ACTTCAGCGA CACCGGCGTG CTCGACGTCT TCGTCGATGA
	AACCCAGGTC

19601	GCGCTGCGTG AACAGCAATT GCGCGATGGC GGCCTGATGC
	CGGGCCGTGA

19651	CCTGGCCTCG ACCTTCTCGA GCCTGCGTCC GAACGACCTG
	GTATGGAACT

19701	ATGTGCAGTC GAACTACCTC AAAGGCAATG AGCCGGCGGC
	GTTTGACCTG

19751	CTGTTCTGGA ATTCGGACAG CACCAATTTG CCGGGCCCGA
	TGTTCTGCTG

19801	GTACCTGCGC AACACCTACC TGGAAAACAG CCTGAAAGTG
	CCGGGCAAGC

19851	TGACGGTGGC CGGCGAAAAG ATCGACCTCG GCCTGATCGA
	CGCCCCGGCC

19901	TTCATCTACG GTTCGCGCGA AGACCACATC GTGCCGTGGA
	TGTCGGCGTA

19951	CGGTTCGCTC GACATCCTCA ACCAGGGCAA GCCGGGCGCC
	AACCGCTTCG

20001	TGCTGGGCGC GTCCGGCCAT ATCGCCGGCG TGATCAACTC
	GGTGGCCAAG

20051	AACAAGCGCA GCTACTGGAT CAACGACGGT GGCGCCGCCG
	ATGCCCAGGC

20101	CTGGTTCGAT GGCGCGCAGG AAGTGCCGGG CAGCTGGTGG
	CCGCAATGGG

20151	CCGGGTTCCT GACCCAGCAT GGCGGCAAGA AGGTCAAGCC
	CAAGGCCAAG

20201	CCCGGCAACG CCCGCTACAC CGCGATCGAG GCGGCGCCCG
	GCCGTTACGT

20251	CAAAGCCAAG GGCTGAGCGG CCGCTGAGTA ATTCTGATAT
	TAGAGGGAGC

20301	ATTAATGTGT TGTTGTGATG TGGTTTATAT GGGGAAATTA
	AATAAATGAT

20351	GTATGTACCT CTTGCCTATG TAGGTTTGTG TGTTTTGTTT
	TGTTGTCTAG

20401	CTTTGGTTAT TAAGTAGTAG GGACGTTCGT TCGTGTCTCA
	AAAAAAGGGG

20451	TACTACCACT CTGTAGTGTA TATGGATGCT GGAAATCAAT
	GTGTTTTGTA

20501	TTTGTTCACC TCCATTGTTG AATTCAATGT CAAATGTGTT
	TTGCGTTGGT

20551	TATGTGTAAA ATTACTATCT TTCTCGTCCG ATGATCAAAG
	TTTTAAGCAA

20601	CAAAACCAAG GGTGAAATTT AAACTGTGCT TTGTTGAAGA
	TTCTTTTATC

20651	ATATTGAAAA TCAAATTACT AGCAGCAGAT TTTACCTAGC
	ATGAAATTTT

20701	ATCAACAGTA CAGCACTCAC TAACCAAGTT CCAAACTAAG
	ATGCGCCATT

20751	AACATCAGCC AATAGGCATT TTCAGCAAGG CGCGCCCGCG
	CCGATGTATG

20801	TGACAACCCT CGGGATTGTT GATTTATTTC AAAACTAAGA
	GTTTTTGTCT

20851	TATTGTTCTC GTCTATTTTG GATATCAATC TTAGTTTTAT
	ATCTTTTCTA

20901	GTTCTCTACG TGTTAAATGT TCAACACACT AGCAATTTGG
	CCTGCCAGCG

20951	TATGGATTAT GGAACTATCA AGTCTGTGAC GCGCCGTACG
	TAGTGTTTAT

21001	CTTTGTTGCT TTTCTGAACA ATTTATTTAC TATGTAAATA
	TATTATCAAT

21051	GTTTAATCTA TTTTAATTTG CACATGAATT TTCATTTTAT
	TTTTACTTTA

21101	CAAAACAAAT AAATATATAT GCAAAAAAAT TTACAAACGA
	TGCACGGGTT

21151	ACAAACTAAT TTCATTAAAT GCTAATGCAG ATTTTGTGAA
	GTAAAACTCC

21201	AATTATGATG AAAAATACCA CCAACACCAC CTGCGAAACT
	GTATCCCAAC

21251	TGTCCTTAAT AAAAATGTTA AAAAGTATAT TATTCTCATT
	TGTCTGTCAT

21301	AATTTATGTA CCCCACTTTA ATTTTTCTGA TGTACTAAAC
	CGAGGGCAAA

21351	CTGAAACCTG TTCCTCATGC AAAGCCCCTA CTCACCATGT
	ATCATGTACG

21401	TGTCATCACC CAACAACTCC ACTTTTGCTA TATAACAACA
	CCCCCGTCAC

21451	ACTCTCCCTC TCTAACACAC ACCCCACTAA CAATTCCTTC
	ACTTGCAGCA

21501	CTGTTGCATC ATCATCTTCA TTGCAAAACC CTAAACTTCA
	CCTTCAACCG

21551	CGGCCGCATG GCTTCTATGA TATCCTCTTC CGCTGTGACA
	ACAGTCAGCC

21601	GTGCCTCTAG GGGGCAATCC GCCGCAGTGG CTCCATTCGG
	CGGCCTCAAA

21651	TCCATGACTG GATTCCCAGT GAAGAAGGTC AACACTGACA
	TTACTTCCAT

21701	TACAAGCAAT GGTGGAAGAG TAAAGTGCAT GCAGGTGTGG
	CCTCCAATTG

21751	GAAAGAAGAA GTTTGAGACT CTTTCCTATT TGCCACCATT
	GACGAGAGAT

21801	TCTAGAGTGA CTCAGCGCAT TGCGTATGTG ACCGGCGGCA
	TGGGTGGTAT

21851	CGGAACCGCC ATTTGCCAGC GGCTGGCCAA GGATGGCTTT
	CGTGTGGTGG

21901	CCGGTTGCGG CCCCAACTCG CCGCGCCGCG AAAAGTGGCT
	GGAGCAGCAG

21951	AAGGCCCTGG GCTTCGATTT CATTGCCTCG GAAGGCAATG
	TGGCTGACTG

22001	GGACTCGACC AAGACCGCAT TCGACAAGGT CAAGTCCGAG
	GTCGGCGAGG

22051	TTGATGTGCT GATCAACAAC GCCGGTATCA CCCGCGACGT
	GGTGTTCCGC

22101	AAGATGACCC GCGCCGACTG GGATGCGGTG ATCGACACCA
	ACCTGACCTC

22151	GCTGTTCAAC GTCACCAAGC AGGTGATCGA CGGCATGGCC
	GACCGTGGCT

22201	GGGGCCGCAT CGTCAACATC TCGTCGGTGA ACGGGCAGAA
	GGGCCAGTTC

22251	GCCATGACCA ACTACTCCAC CGCCAAGGCC GGCCTGCATG
	GCTTCACCAT

22301	GGCACTGGCG CAGGAAGTGG CGACCAAGGG CGTGACCGTC
	AACACGGTCT

22351	CTCCGGGCTA TATCGCCACC GACATGGTCA AGGCGATCCG
	CCAGGACGTG

22401	CTCGACAAGA TCGTCGCGAC GATCCCGGTC AAGCGCCTGG
	GCCTGCCGGA

22451	AGAGATCGCC TCGATCTGCG CCTGGTTGTC GTCGGAGGAG
	TCCGGTTTCT

22501	CGACCGGCGC CGACTTCTCG CTCAACGGCG GCCTGCATAT
	GGGCTGAGCG

22551	GCCGCTGAGT AATTCTGATA TTAGAGGGAG CATTAATGTG
	TTGTTGTGAT

22601	GTGGTTTATA TGGGGAAATT AAATAAATGA TGTATGTACC
	TCTTGCCTAT

22651	GTAGGTTTGT GTGTTTTGTT TTGTTGTCTA GCTTTGGTTA
	TTAAGTAGTA

22701	GGGACGTTCG TTCGTGTCTC AAAAAAAGGG GTACTACCAC
	TCTGTAGTGT

22751	ATATGGATGC TGGAAATCAA TGTGTTTTGT ATTTGTTCAC
	CTCCATTGTT

22801	GAATTCAATG TCAAATGTGT TTTGCGTTGG TTATGTGTAA
	AATTACTATC

22851	TTTCTCGTCC GATGATCAAA GTTTTAAGCA ACAAAACCAA
	GGGTGAAATT

22901	TAAACTGTGC TTTGTTGAAG ATTCTTTTAT CATATTGAAA
	ATCAAATTAC

22951	TAGCAGCAGA TTTTACCTAG CATGAAATTT TATCAACAGT
	ACAGCACTCA

23001	CTAACCAAGT TCCAAACTAA GATGCGCCAT TAACATCAGC
	CAATAGGCAT

23051	TTTCAGCAAG GCGCGTAA

Vector: pMBXS407

(SEQ ID NO: 9)

1	GGGGATCCGT ACGTAAGTAC GTACTCAAAA TGCCAACAAA
	TAAAAAAAAA

51	GTTGCTTTAA TAATGCCAAA ACAAATTAAT AAAACACTTA
	CAACACCGGA

101	TTTTTTTTAA TTAAAATGTG CCATTTAGGA TAAATAGTTA
	ATATTTTTAA

151	TAATTATTTA AAAAGCCGTA TCTACTAAAA TGATTTTTAT
	TTGGTTGAAA

201	ATATTAATAT GTTTAAATCA ACACAATCTA TCAAAATTAA
	ACTAAAAAAA

251	AAATAAGTGT ACGTGGTTAA CATTAGTACA GTAATATAAG
	AGGAAAATGA

301	GAAATTAAGA AATTGAAAGC GAGTCTAATT TTTAAATTAT
	GAACCTGCAT

351	ATATAAAAGG AAAGAAAGAA TCCAGGAAGA AAAGAAATGA
	AACCATGCAT

401	GGTCCCCTCG TCATCACGAG TTTCTGCCAT TTGCAATAGA
	AACACTGAAA

451	CACCTTTCTC TTTGTCACTT AATTGAGATG CCGAAGCCAC
	CTCACACCAT

501	GAACTTCATG AGGTGTAGCA CCCAAGGCTT CCATAGCCAT
	GCATACTGAA

551	GAATGTCTCA AGCTCAGCAC CCTACTTCTG TGACGTGTCC
	CTCATTCACC

601	TTCCTCTCTT CCCTATAAAT AACCACGCCT CAGGTTCTCC
	GCTTCACAAC

651	TCAAACATTC TCTCCATTGG TCCTTAAACA CTCATCAGTC
	ATCACCGCGG

701	CCGCGGAATT CATGGCTTCT ATGATATCCT CTTCCGCTGT
	GACAACAGTC

751	AGCCGTGCCT CTAGGGGGCA ATCCGCCGCA GTGGCTCCAT
	TCGGCGGCCT

801	CAAATCCATG ACTGGATTCC CAGTGAAGAA GGTCAACACT
	GACATTACTT

851	CCATTACAAG CAATGGTGGA AGAGTAAAGT GCATGCAGGT
	GTGGCCTCCA

901	ATTGGAAAGA AGAAGTTTGA GACTCTTTCC TATTTGCCAC
	CATTGACGAG

951	AGATTCTAGA GTGACTGACG TTGTCATCGT ATCCGCCGCC
	CGCACCGCGG

1001	TCGGCAAGTT TGGCGGCTCG CTGGCCAAGA TCCCGGCACC
	GGAACTGGGT

1051	GCCGTGGTCA TCAAGGCCGC GCTGGAGCGC GCCGGCGTCA
	AGCCGGAGCA

1101	GGTGAGCGAA GTCATCATGG GCCAGGTGCT GACCGCCGGT
	TCGGGCCAGA

1151	ACCCCGCACG CCAGGCCGCG ATCAAGGCCG GCCTGCCGGC
	GATGGTGCCG

1201	GCCATGACCA TCAACAAGGT GTGCGGCTCG GGCCTGAAGG
	CCGTGATGCT

1251	GGCCGCCAAC GCGATCATGG CGGGCGACGC CGAGATCGTG
	GTGGCCGGCG

1301	GCCAGGAAAA CATGAGCGCC GCCCCGCACG TGCTGCCGGG
	CTCGCGCGAT

1351	GGTTTCCGCA TGGGCGATGC CAAGCTGGTC GACACCATGA
	TCGTCGACGG

1401	CCTGTGGGAC GTGTACAACC AGTACCACAT GGGCATCACC
	GCCGAGAACG

1451	TGGCCAAGGA ATACGGCATC ACACGCGAGG CGCAGGATGA
	GTTCGCCGTC

1501	GGCTCGCAGA ACAAGGCCGA AGCCGCGCAG AAGGCCGGCA
	AGTTTGACGA

1551	AGAGATCGTC CCGGTGCTGA TCCCGCAGCG CAAGGGCGAC
	CCGGTGGCCT

1601	TCAAGACCGA CGAGTTCGTG CGCCAGGGCG CCACGCTGGA
	CAGCATGTCC

1651	GGCCTCAAGC CCGCCTTCGA CAAGGCCGGC ACGGTGACCG
	CGGCCAACGC

1701	CTCGGGCCTG AACGACGGCG CCGCCGCGGT GGTGGTGATG
	TCGGCGGCCA

1751	AGGCCAAGGA ACTGGGCCTG ACCCCGCTGG CCACGATCAA
	GAGCTATGCC

1801	AACGCCGGTG TCGATCCCAA GGTGATGGGC ATGGGCCCGG
	TGCCGGCCTC

1851	CAAGCGCGCC CTGTCGCGCG CCGAGTGGAC CCCGCAAGAC
	CTGGACCTGA

1901	TGGAGATCAA CGAGGCCTTT GCCGCGCAGG CGCTGGCGGT
	GCACCAGCAG

1951	ATGGGCTGGG ACACCTCCAA GGTCAATGTG AACGGCGGCG
	CCATCGCCAT

2001	CGGCCACCCG ATCGGCGCGT CGGGCTGCCG TATCCTGGTG
	ACGCTGCTGC

2051	ACGAGATGAA GCGCCGTGAC GCGAAGAAGG GCCTGGCCTC
	GCTGTGCATC

2101	GGCGGCGGCA TGGGCGTGGC GCTGGCAGTC GAGCGCAAAT
	AACTCGAGGC

2151	GGCCGCAGCC CTTTTTGTAT GTGCTACCCC ACTTTTGTCT
	TTTTGGCAAT

2201	AGTGCTAGCA ACCAATAAAT AATAATAATA ATAATGAATA
	AGAAAACAAA

2251	GGCTTTAGCT TGCCTTTTGT TCACTGTAAA ATAATAATGT
	AAGTACTCTC

2301	TATAATGAGT CACGAAACTT TTGCGGGAAT AAAAGGAGAA
	ATTCCAATGA

2351	GTTTTCTGTC AAATCTTCTT TTGTCTCTCT CTCTCTCTCT
	TTTTTTTTTT

2401	TCTTTCTTCT GAGCTTCTTG CAAAACAAAA GGCAAACAAT
	AACGATTGGT

2451	CCAATGATAG TTAGCTTGAT CGATGATATC TTTAGGAAGT
	GTTGGCAGGA

2501	CAGGACATGA TGTAGAAGAC TAAAATTGAA AGTATTGCAG
	ACCCAATAGT

2551	TGAAGATTAA CTTTAAGAAT GAAGACGTCT TATCAGGTTC
	TTCATGACTT

2601	AAGCTTTAAG AGGAGTCCAC CATGGTAGAT CTGACTAGTA
	ACGGCCGCCA

2651	GTGTGCTGGA ATTCTGCAGA TGTGGAGCAC GACACTCTCG
	TCTACTCCAA

2701	GAATATCAAA GATACAGTCT CAGAAGACCA AAGGGCTATT
	GAGACTTTTC

2751	AACAAAGGGT AATATCGGGA AACCTCCTCG GATTCCATTG
	CCCAGCTATC

2801	TGTCACTTCA TCAAAAGGAC AGTAGAAAAG GAAGGTGGCA
	CCTACAAATG

2851	CCATCATTGC GATAAAGGAA AGGCTATCGT TCAAGATGCC
	TCTGCCGACA

2901	GTGGTCCCAA AGATGGACCC CCACCCACGA GGAGCATCGT
	GGAAAAAGAA

2951	GACGTTCCAA CCACGTCTTC AAAGCAAGTG GATTGATGTG
	ATAACATGGT

3001	GGAGCACGAC ACTCTCGTCT ACTCCAAGAA TATCAAAGAT
	ACAGTCTCAG

3051	AAGACCAAAG GGCTATTGAG ACTTTTCAAC AAAGGGTAAT
	ATCGGGAAAC

3101	CTCCTCGGAT TCCATTGCCC AGCTATCTGT CACTTCATCA
	AAAGGACAGT

3151	AGAAAAGGAA GGTGGCACCT ACAAATGCCA TCATTGCGAT
	AAAGGAAAGG

3201	CTATCGTTCA AGATGCCTCT GCCGACAGTG GTCCCAAAGA
	TGGACCCCCA

3251	CCCACGAGGA GCATCGTGGA AAAAGAAGAC GTTCCAACCA
	CGTCTTCAAA

3301	GCAAGTGGAT TGATGTGATA TCTCCACTGA CGTAAGGGAT
	GACGCACAAT

3351	CCCACTATCC TTCGCAAGAC CTTCCTCTAT ATAAGGAAGT
	TCATTTCATT

3401	TGGAGAGGAC ACGCTGAAAT CACCAGTCTC TCTCTACAAA
	TCTATCTCTC

3451	TCGAGTTAAT TAAAATGGCT TCTATGATAT CCTCTTCCGC
	TGTGACAACA

3501	GTCAGCCGTG CCTCTAGGGG GCAATCCGCC GCAGTGGCTC
	CATTCGGCGG

3551	CCTCAAATCC ATGACTGGAT TCCCAGTGAA GAAGGTCAAC
	ACTGACATTA

3601	CTTCCATTAC AAGCAATGGT GGAAGAGTAA AGTGCATGCA
	GGTGTGGCCT

3651	CCAATTGGAA AGAAGAAGTT TGAGACTCTT TCCTATTTGC
	CACCATTGAC

3701	GAGAGATTCT AGAGTGGAGA AGACGATCGG TCTCGAGATT
	ATTGAAGTTG

3751	TCGAGCAGGC AGCGATCGCC TCGGCCCGCC TGATGGGCAA
	AGGCGAAAAG

3801	AATGAAGCCG ATCGCGTCGC AGTAGAAGCG ATGCGGGTGC
	GGATGAACCA

3851	AGTGGAAATG CTGGGCCGCA TCGTCATCGG TGAAGGCGAG
	CGCGACGAAG

3901	CACCGATGCT CTATATCGGT GAAGAAGTGG GCATCTACCG
	CGATGCAGAC

3951	AAGCGGGCTG GCGTACCGGC TGGCAAGCTG GTGGAAATCG
	ACATCGCCGT

4001	TGACCCCTGC GAAGGCACCA ACCTCTGCGC CTACGGTCAG
	CCCGGCTCGA

4051	TGGCAGTTTT GGCCATCTCC GAGAAAGGCG GCCTGTTTGC
	AGCTCCCGAC

4101	TTCTACATGA AGAAACTGGC TGCACCCCCA GCTGCCAAAG
	GCAAAGTAGA

4151	CATCAATAAG TCCGCGACCG AAAACCTGAA AATTCTCTCG
	GAATGTCTCG

4201	ATCGCGCCAT CGATGAATTG GTGGTCGTGG TCATGGATCG
	TCCCCGCCAC

4251	AAAGAGCTAA TCCAAGAGAT CCGCCAAGCG GGTGCCCGCG
	TCCGTCTGAT

4301	CAGCGATGGT GACGTTTCGG CCGCGATCTC CTGCGGTTTT
	GCTGGCACCA

4351	ACACCCACGC CCTGATGGGC ATCGGTGCAG CTCCCGAGGG
	TGTGATTTCG

4401	GCAGCAGCAA TGCGTTGCCT CGGCGGTCAC TTCCAAGGCC
	AGCTGATCTA

4451	CGACCCAGAA GTGGTCAAAA CCGGCCTGAT CGGTGAAAGC
	CGTGAGAGCA

4501	ACATCGCTCG CCTGCAAGAA ATGGGCATCA CCGATCCCGA
	TCGCGTCTAC

4551	GACGCCAACG AACTGGCTTC GGGTCAAGAA GTGCTGTTTG
	CGGCTTGCGG

4601	TATCACCCCG GGCTTGCTGA TGGAAGGCGT GCGCTTCTTC
	AAAGGCGGCG

4651	CTCGCACCCA GAGCTTGGTG ATCTCCAGCC AGTCACGGAC
	GGCTCGCTTC

4701	GTTGACACCG TTCACATGTT CGACGATGTC AAAACGGTTA
	GCCTCCGTTA

4751	ATTCCTGATC CCAAATGGCG GCCGGAGCGG TAGGGCGCGC
	CATCGTTCAA

4801	ACATTTGGCA ATAAAGTTTC TTAAGATTGA ATCCTGTTGC
	CGGTCTTGCG

4851	ATGATTATCA TATAATTTCT GTTGAATTAC GTTAAGCATG
	TAATAATTAA

4901	CATGTAATGC ATGACGTTAT TTATGAGATG GGTTTTTATG
	ATTAGAGTCC

4951	CGCAATTATA CATTTAATAC GCGATAGAAA ACAAAATATA
	GCGCGCAAAC

5001	TAGGATAAAT TATCGCGCGC GGTGTCATCT ATGTTACTAG
	ATCCGATGAT

5051	AAGCTGTCAA ACATGAATTT AAATACTAGT AGAAGGTAAT
	TATCCAAGAT

5101	GTAGCATCAA GAATCCAATG TTTACGGGAA AAACTATGGA
	AGTATTATGT

5151	GAGCTCAGCA AGAAGCAGAT CAATATGCGG CACATATGCA
	ACCTATGTTC

5201	AAAAATGAAG AATGTACAGA TACAAGATCC TATACTGCCA
	GAATACGAAG

5251	AAGAATACGT AGAAATTGAA AAAGAAGAAC CAGGCGAAGA
	AAAGAATCTT

5301	GAAGACGTAA GCACTGACGA CAACAATGAA AAGAAGAAGA
	TAAGGTCGGT

5351	GATTGTGAAA GAGACATAGA GGACACATGT AAGGTGGAAA
	ATGTAAGGGC

5401	GGAAAGTAAC CTTATCACAA AGGAATCTTA TCCCCCACTA
	CTTATCCTTT

5451	TATATTTTTC CGTGTCATTT TTGCCCTTGA GTTTTCCTAT
	ATAAGGAACC

5501	AAGTTCGGCA TTTGTGAAAA CAAGAAAAAA TTGGTGTAAG
	CTATTTTCTT

5551	TGAAGTACTG AGGATACAAC TTCAGAGAAA TTTGTAAGAA
	AGTGGATCGA

5601	AACCATGGCC TCCTCCGAGA ACGTCATCAC CGAGTTCATG
	CGCTTCAAGG

5651	TGCGCATGGA GGGCACCGTG AACGGCCACG AGTTCGAGAT
	CGAGGGCGAG

5701	GGCGAGGGCC GCCCCTACGA GGGCCACAAC ACCGTGAAGC
	TGAAGGTGAC

5751	CAAGGGCGGC CCCCTGCCCT TCGCCTGGGA CATCCTGTCC
	CCCCAGTTCC

5801	AGTACGGCTC CAAGGTGTAC GTGAAGCACC CCGCCGACAT
	CCCCGACTAC

5851	AAGAAGCTGT CCTTCCCCGA GGGCTTCAAG TGGGAGCGCG
	TGATGAACTT

5901	CGAGGACGGC GGCGTGGCGA CCGTGACCCA GGACTCCTCC
	CTGCAGGACG

5951	GCTGCTTCAT CTACAAGGTG AAGTTCATCG GCGTGAACTT
	CCCCTCCGAC

6001	GGCCCCGTGA TGCAGAAGAA GACCATGGGC TGGGAGGCCT
	CCACCGAGCG

6051	CCTGTACCCC CGCGACGGCG TGCTGAAGGG CGAGACCCAC
	AAGGCCCTGA

6101	AGCTGAAGGA CGGCGGCCAC TACCTGGTGG AGTTCAAGTC
	CATCTACATG

6151	GCCAAGAAGC CCGTGCAGCT GCCCGGCTAC TACTACGTGG
	ACGCCAAGCT

6201	GGACATCACC TCCCACAACG AGGACTACAC CATCGTGGAG
	CAGTACGAGC

6251	GCACCGAGGG CCGCCACCAC CTGTTCCTGG TACCAATGAG
	CTCTGTCCAA

6301	CAGTCTCAGG GTTAATGTCT ATGTATCTTA AATAATGTTG
	TCGGCGATCG

6351	TTCAAACATT TGGCAATAAA GTTTCTTAAG ATTGAATCCT
	GTTGCCGGTC

6401	TTGCGATGAT TATCATATAA TTTCTGTTGA ATTACGTTAA
	GCATGTAATA

6451	ATTAACATGT AATGCATGAC GTTATTTATG AGATGGGTTT
	TTATGATTAG

6501	AGTCCCGCAA TTATACATTT AATACGCGAT AGAAAACAAA
	ATATAGCGCG

6551	CAAACTAGGA TAAATTATCG CGCGCGGTGT CATCTATGTT
	ACTAGATCGG

6601	GAATTAAACT ATCAGTGTTT GACAGGATAT ATTGGCGGGT
	AAACCTAAGA

6651	GAAAAGAGCG TTTATTAGAA TAACGGATAT TTAAAAGGGC
	GTGAAAAGGT

6701	TTATCCGTTC GTCCATTTGT ATGTGCATGC CAACCACAGG
	GTTCCCCTCG

6751	GGATCAAAGT ACTTTGATCC AACCCCTCCG CTGCTATAGT
	GCAGTCGGCT

6801	TCTGACGTTC AGTGCAGCCG TCTTCTGAAA ACGACATGTC
	GCACAAGTCC

6851	TAAGTTACGC GACAGGCTGC CGCCCTGCCC TTTTCCTGGC
	GTTTTCTTGT

6901	CGCGTGTTTT AGTCGCATAA AGTAGAATAC TTGCGACTAG
	AACCGGAGAC

6951	ATTACGCCAT GAACAAGAGC GCCGCCGCTG GCCTGCTGGG
	CTATGCCCGC

7001	GTCAGCACCG ACGACCAGGA CTTGACCAAC CAACGGGCCG
	AACTGCACGC

7051	GGCCGGCTGC ACCAAGCTGT TTTCCGAGAA GATCACCGGC
	ACCAGGCGCG

7101	ACCGCCCGGA GCTGGCCAGG ATGCTTGACC ACCTACGCCC
	TGGCGACGTT

7151	GTGACAGTGA CCAGGCTAGA CCGCCTGGCC CGCAGCACCC
	GCGACCTACT

7201	GGACATTGCC GAGCGCATCC AGGAGGCCGG CGCGGGCCTG
	CGTAGCCTGG

7251	CAGAGCCGTG GGCCGACACC ACCACGCCGG CCGGCCGCAT
	GGTGTTGACC

7301	GTGTTCGCCG GCATTGCCGA GTTCGAGCGT TCCCTAATCA
	TCGACCGCAC

7351	CCGGAGCGGG CGCGAGGCCG CCAAGGCCCG AGGCGTGAAG
	TTTGGCCCCC

7401	GCCCTACCCT CACCCCGGCA CAGATCGCGC ACGCCCGCGA
	GCTGATCGAC

7451	CAGGAAGGCC GCACCGTGAA AGAGGCGGCT GCACTGCTTG
	GCGTGCATCG

7501	CTCGACCCTG TACCGCGCAC TTGAGCGCAG CGAGGAAGTG
	ACGCCCACCG

7551	AGGCCAGGCG GCGCGGTGCC TTCCGTGAGG ACGCATTGAC
	CGAGGCCGAC

7601	GCCCTGGCGG CCGCCGAGAA TGAACGCCAA GAGGAACAAG
	CATGAAACCG

7651	CACCAGGACG GCCAGGACGA ACCGTTTTTC ATTACCGAAG
	AGATCGAGGC

7701	GGAGATGATC GCGGCCGGGT ACGTGTTCGA GCCGCCCGCG
	CACGTCTCAA

7751	CCGTGCGGCT GCATGAAATC CTGGCCGGTT TGTCTGATGC
	CAAGCTGGCG

7801	GCCTGGCCGG CCAGCTTGGC CGCTGAAGAA ACCGAGCGCC
	GCCGTCTAAA

7851	AAGGTGATGT GTATTTGAGT AAAACAGCTT GCGTCATGCG
	GTCGCTGCGT

7901	ATATGATGCG ATGAGTAAAT AAACAAATAC GCAAGGGGAA
	CGCATGAAGG

7951	TTATCGCTGT ACTTAACCAG AAAGGCGGGT CAGGCAAGAC
	GACCATCGCA

8001	ACCCATCTAG CCCGCGCCCT GCAACTCGCC GGGGCCGATG
	TTCTGTTAGT

8051	CGATTCCGAT CCCCAGGGCA GTGCCCGCGA TTGGGCGGCC
	GTGCGGGAAG

8101	ATCAACCGCT AACCGTTGTC GGCATCGACC GCCCGACGAT
	TGACCGCGAC

8151	GTGAAGGCCA TCGGCCGGCG CGACTTCGTA GTGATCGACG
	GAGCGCCCCA

8201	GGCGGCGGAC TTGGCTGTGT CCGCGATCAA GGCAGCCGAC
	TTCGTGCTGA

8251	TTCCGGTGCA GCCAAGCCCT TACGACATAT GGGCCACCGC
	CGACCTGGTG

8301	GAGCTGGTTA AGCAGCGCAT TGAGGTCACG GATGGAAGGC
	TACAAGCGGC

8351	CTTTGTCGTG TCGCGGGCGA TCAAAGGCAC GCGCATCGGC
	GGTGAGGTTG

8401	CCGAGGCGCT GGCCGGGTAC GAGCTGCCCA TTCTTGAGTC
	CCGTATCACG

8451	CAGCGCGTGA GCTACCCAGG CACTGCCGCC GCCGGCACAA
	CCGTTCTTGA

8501	ATCAGAACCC GAGGGCGACG CTGCCCGCGA GGTCCAGGCG
	CTGGCCGCTG

8551	AAATTAAATC AAAACTCATT TGAGTTAATG AGGTAAAGAG
	AAAATGAGCA

8601	AAAGCACAAA CACGCTAAGT GCCGGCCGTC CGAGCGCACG
	CAGCAGCAAG

8651	GCTGCAACGT TGGCCAGCCT GGCAGACACG CCAGCCATGA
	AGCGGGTCAA

8701	CTTTCAGTTG CCGGCGGAGG ATCACACCAA GCTGAAGATG
	TACGCGGTAC

8751	GCCAAGGCAA GACCATTACC GAGCTGCTAT CTGAATACAT
	CGCGCAGCTA

8801	CCAGAGTAAA TGAGCAAATG AATAAATGAG TAGATGAATT
	TTAGCGGCTA

8851	AAGGAGGCGG CATGGAAAAT CAAGAACAAC CAGGCACCGA
	CGCCGTGGAA

8901	TGCCCCATGT GTGGAGGAAC GGGCGGTTGG CCAGGCGTAA
	GCGGCTGGGT

8951	TGTCTGCCGG CCCTGCAATG GCACTGGAAC CCCCAAGCCC
	GAGGAATCGG

9001	CGTGACGGTC GCAAACCATC CGGCCCGGTA CAAATCGGCG
	CGGCGCTGGG

9051	TGATGACCTG GTGGAGAAGT TGAAGGCCGC GCAGGCCGCC
	CAGCGGCAAC

9101	GCATCGAGGC AGAAGCACGC CCCGGTGAAT CGTGGCAAGC
	GGCCGCTGAT

9151	CGAATCCGCA AAGAATCCCG GCAACCGCCG GCAGCCGGTG
	CGCCGTCGAT

9201	TAGGAAGCCG CCCAAGGGCG ACGAGCAACC AGATTTTTTC
	GTTCCGATGC

9251	TCTATGACGT GGGCACCCGC GATAGTCGCA GCATCATGGA
	CGTGGCCGTT

9301	TTCCGTCTGT CGAAGCGTGA CCGACGAGCT GGCGAGGTGA
	TCCGCTACGA

9351	GCTTCCAGAC GGGCACGTAG AGGTTTCCGC AGGGCCGGCC
	GGCATGGCCA

9401	GTGTGTGGGA TTACGACCTG GTACTGATGG CGGTTTCCCA
	TCTAACCGAA

9451	TCCATGAACC GATACCGGGA AGGGAAGGGA GACAAGCCCG
	GCCGCGTGTT

9501	CCGTCCACAC GTTGCGGACG TACTCAAGTT CTGCCGGCGA
	GCCGATGGCG

9551	GAAAGCAGAA AGACGACCTG GTAGAAACCT GCATTCGGTT
	AAACACCACG

9601	CACGTTGCCA TGCAGCGTAC GAAGAAGGCC AAGAACGGCC
	GCCTGGTGAC

9651	GGTATCCGAG GGTGAAGCCT TGATTAGCCG CTACAAGATC
	GTAAAGAGCG

9701	AAACCGGGCG GCCGGAGTAC ATCGAGATCG AGCTAGCTGA
	TTGGATGTAC

9751	CGCGAGATCA CAGAAGGCAA GAACCCGGAC GTGCTGACGG
	TTCACCCCGA

9801	TTACTTTTTG ATCGATCCCG GCATCGGCCG TTTTCTCTAC
	CGCCTGGCAC

9851	GCCGCGCCGC AGGCAAGGCA GAAGCCAGAT GGTTGTTCAA
	GACGATCTAC

9901	GAACGCAGTG GCAGCGCCGG AGAGTTCAAG AAGTTCTGTT
	TCACCGTGCG

9951	CAAGCTGATC GGGTCAAATG ACCTGCCGGA GTACGATTTG
	AAGGAGGAGG

10001	CGGGGCAGGC TGGCCCGATC CTAGTCATGC GCTACCGCAA
	CCTGATCGAG

10051	GGCGAAGCAT CCGCCGGTTC CTAATGTACG GAGCAGATGC
	TAGGGCAAAT

10101	TGCCCTAGCA GGGGAAAAAG GTCGAAAAGG TCTCTTTCCT
	GTGGATAGCA

10151	CGTACATTGG GAACCCAAAG CCGTACATTG GGAACCGGAA
	CCCGTACATT

10201	GGGAACCCAA AGCCGTACAT TGGGAACCGG TCACACATGT
	AAGTGACTGA

10251	TATAAAAGAG AAAAAAGGCG ATTTTTCCGC CTAAAACTCT
	TTAAAACTTA

10301	TTAAAACTCT TAAAACCCGC CTGGCCTGTG CATAACTGTC
	TGGCCAGCGC

10351	ACAGCCGAAG AGCTGCAAAA AGCGCCTACC CTTCGGTCGC
	TGCGCTCCCT

10401	ACGCCCCGCC GCTTCGCGTC GGCCTATCGC GGCCGCTGGC
	CGCTCAAAAA

10451	TGGCTGGCCT ACGGCCAGGC AATCTACCAG GGCGCGGACA
	AGCCGCGCCG

10501	TCGCCACTCG ACCGCCGGCG CCCACATCAA GGCACCCTGC
	CTCGCGCGTT

10551	TCGGTGATGA CGGTGAAAAC CTCTGACACA TGCAGCTCCC
	GGAGACGGTC

10601	ACAGCTTGTC TGTAAGCGGA TGCCGGGAGC AGACAAGCCC
	GTCAGGGCGC

10651	GTCAGCGGGT GTTGGCGGGT GTCGGGGCGC AGCCATGACC
	CAGTCACGTA

10701	GCGATAGCGG AGTGTATACT GGCTTAACTA TGCGGCATCA
	GAGCAGATTG

10751	TACTGAGAGT GCACCATATG CGGTGTGAAA TACCGCACAG
	ATGCGTAAGG

10801	AGAAAATACC GCATCAGGCG CTCTTCCGCT TCCTCGCTCA
	CTGACTCGCT

10851	GCGCTCGGTC GTTCGGCTGC GGCGAGCGGT ATCAGCTCAC
	TCAAAGGCGG

10901	TAATACGGTT ATCCACAGAA TCAGGGGATA ACGCAGGAAA
	GAACATGTGA

10951	GCAAAAGGCC AGCAAAAGGC CAGGAACCGT AAAAAGGCCG
	CGTTGCTGGC

11001	GTTTTTCCAT AGGCTCCGCC CCCCTGACGA GCATCACAAA
	AATCGACGCT

11051	CAAGTCAGAG GTGGCGAAAC CCGACAGGAC TATAAAGATA
	CCAGGCGTTT

11101	CCCCCTGGAA GCTCCCTCGT GCGCTCTCCT GTTCCGACCC
	TGCCGCTTAC

11151	CGGATACCTG TCCGCCTTTC TCCCTTCGGG AAGCGTGGCG
	CTTTCTCATA

11201	GCTCACGCTG TAGGTATCTC AGTTCGGTGT AGGTCGTTCG
	CTCCAAGCTG

11251	GGCTGTGTGC ACGAACCCCC CGTTCAGCCC GACCGCTGCG
	CCTTATCCGG

11301	TAACTATCGT CTTGAGTCCA ACCCGGTAAG ACACGACTTA
	TCGCCACTGG

11351	CAGCAGCCAC TGGTAACAGG ATTAGCAGAG CGAGGTATGT
	AGGCGGTGCT

11401	ACAGAGTTCT TGAAGTGGTG GCCTAACTAC GGCTACACTA
	GAAGGACAGT

11451	ATTTGGTATC TGCGCTCTGC TGAAGCCAGT TACCTTCGGA
	AAAAGAGTTG

11501	GTAGCTCTTG ATCCGGCAAA CAAACCACCG CTGGTAGCGG
	TGGTTTTTTT

11551	GTTTGCAAGC AGCAGATTAC GCGCAGAAAA AAAGGATCTC
	AAGAAGATCC

11601	TTTGATCTTT TCTACGGGGT CTGACGCTCA GTGGAACGAA
	AACTCACGTT

11651	AAGGGATTTT GGTCATGCAT TCTAGGTACT AAAACAATTC
	ATCCAGTAAA

11701	ATATAATATT TTATTTTCTC CCAATCAGGC TTGATCCCCA
	GTAAGTCAAA

11751	AAATAGCTCG ACATACTGTT CTTCCCCGAT ATCCTCCCTG
	ATCGACCGGA

11801	CGCAGAAGGC AATGTCATAC CACTTGTCCG CCCTGCCGCT
	TCTCCCAAGA

11851	TCAATAAAGC CACTTACTTT GCCATCTTTC ACAAAGATGT
	TGCTGTCTCC

11901	CAGGTCGCCG TGGGAAAAGA CAAGTTCCTC TTCGGGCTTT
	TCCGTCTTTA

11951	AAAAATCATA CAGCTCGCGC GGATCTTTAA ATGGAGTGTC
	TTCTTCCCAG

12001	TTTTCGCAAT CCACATCGGC CAGATCGTTA TTCAGTAAGT
	AATCCAATTC

12051	GGCTAAGCGG CTGTCTAAGC TATTCGTATA GGGACAATCC
	GATATGTCGA

12101	TGGAGTGAAA GAGCCTGATG CACTCCGCAT ACAGCTCGAT
	AATCTTTTCA

12151	GGGCTTTGTT CATCTTCATA CTCTTCCGAG CAAAGGACGC
	CATCGGCCTC

12201	ACTCATGAGC AGATTGCTCC AGCCATCATG CCGTTCAAAG
	TGCAGGACCT

12251	TTGGAACAGG CAGCTTTCCT TCCAGCCATA GCATCATGTC
	CTTTTCCCGT

12301	TCCACATCAT AGGTGGTCCC TTTATACCGG CTGTCCGTCA
	TTTTTAAATA

12351	TAGGTTTTCA TTTTCTCCCA CCAGCTTATA TACCTTAGCA
	GGAGACATTC

12401	CTTCCGTATC TTTTACGCAG CGGTATTTTT CGATCAGTTT
	TTTCAATTCC

12451	GGTGATATTC TCATTTTAGC CATTTATTAT TTCCTTCCTC
	TTTTCTACAG

12501	TATTTAAAGA TACCCCAAGA AGCTAATTAT AACAAGACGA
	ACTCCAATTC

12551	ACTGTTCCTT GCATTCTAAA ACCTTAAATA CCAGAAAACA
	GCTTTTTCAA

12601	AGTTGTTTTC AAAGTTGGCG TATAACATAG TATCGACGGA
	GCCGATTTTG

12651	AAACCGCGGT GATCACAGGC AGCAACGCTC TGTCATCGTT
	ACAATCAACA

12701	TGCTACCCTC CGCGAGATCA TCCGTGTTTC AAACCCGGCA
	GCTTAGTTGC

12751	CGTTCTTCCG AATAGCATCG GTAACATGAG CAAAGTCTGC
	CGCCTTACAA

12801	CGGCTCTCCC GCTGACGCCG TCCCGGACTG ATGGGCTGCC
	TGTATCGAGT

12851	GGTGATTTTG TGCCGAGCTG CCGGTCGGGG AGCTGTTGGC
	TGGCTGGTGG

12901	CAGGATATAT TGTGGTGTAA ACAAATTGAC GCTTAGACAA
	CTTAATAACA

12951	CATTGCGGAC GTTTTTAATG TACTGAATTA ACGCCGAATT
	AATTCCTAGG

13001	CCACCATGTT GGGCCCGGGG CGCGCCGTAC GTAGTGTTTA
	TCTTTGTTGC

13051	TTTTCTGAAC AATTTATTTA CTATGTAAAT ATATTATCAA
	TGTTTAATCT

13101	ATTTTAATTT GCACATGAAT TTTCATTTTA TTTTTACTTT
	ACAAAACAAA

13151	TAAATATATA TGCAAAAAAA TTTACAAACG ATGCACGGGT
	TACAAACTAA

13201	TTTCATTAAA TGCTAATGCA GATTTTGTGA AGTAAAACTC
	CAATTATGAT

13251	GAAAAATACC ACCAACACCA CCTGCGAAAC TGTATCCCAA
	CTGTCCTTAA

13301	TAAAAATGTT AAAAAGTATA TTATTCTCAT TTGTCTGTCA
	TAATTTATGT

13351	ACCCCACTTT AATTTTTCTG ATGTACTAAA CCGAGGGCAA
	ACTGAAACCT

13401	GTTCCTCATG CAAAGCCCCT ACTCACCATG TATCATGTAC
	GTGTCATCAC

13451	CCAACAACTC CACTTTTGCT ATATAACAAC ACCCCCGTCA
	CACTCTCCCT

13501	CTCTAACACA CACCCCACTA ACAATTCCTT CACTTGCAGC
	ACTGTTGCAT

13551	CATCATCTTC ATTGCAAAAC CCTAAACTTC ACCTTCAACC
	GCGGCCGCAT

13601	GGCTTCTATG ATATCCTCTT CCGCTGTGAC AACAGTCAGC
	CGTGCCTCTA

13651	GGGGGCAATC CGCCGCAGTG GCTCCATTCG GCGGCCTCAA
	ATCCATGACT

13701	GGATTCCCAG TGAAGAAGGT CAACACTGAC ATTACTTCCA
	TTACAAGCAA

13751	TGGTGGAAGA GTAAAGTGCA TGCAGGTGTG GCCTCCAATT
	GGAAAGAAGA

13801	AGTTTGAGAC TCTTTCCTAT TTGCCACCAT TGACGAGAGA
	TTCTAGAGTG

13851	AGTAACAAGA ACAACGATGA GCTGCAGTGG CAATCCTGGT
	TCAGCAAGGC

13901	GCCCACCACC GAGGCGAACC CGATGGCCAC CATGTTGCAG
	GATATCGGCG

13951	TTGCGCTCAA ACCGGAAGCG ATGGAGCAGC TGAAAAACGA
	TTATCTGCGT

14001	GACTTCACCG CGTTGTGGCA GGATTTTTTG GCTGGCAAGG
	CGCCAGCCGT

14051	CAGCGACCGC CGCTTCAGCT CGGCAGCCTG GCAGGGCAAT
	CCGATGTCGG

14101	CCTTCAATGC CGCATCTTAC CTGCTCAACG CCAAATTCCT
	CAGTGCCATG

14151	GTGGAGGCGG TGGACACCGC ACCCCAGCAA AAGCAGAAAA
	TACGCTTTGC

14201	CGTGCAGCAG GTGATTGATG CCATGTCGCC CGCGAACTTC
	CTCGCCACCA

14251	ACCCGGAAGC GCAGCAAAAA CTGATTGAAA CCAAGGGCGA
	GAGCCTGACG

14301	CGTGGCCTGG TCAATATGCT GGGCGATATC AACAAGGGCC
	ATATCTCGCT

14351	GTCGGACGAA TCGGCCTTTG AAGTGGGCCG CAACCTGGCC
	ATTACCCCGG

14401	GCACCGTGAT TTACGAAAAT CCGCTGTTCC AGCTGATCCA
	GTACACGCCG

14451	ACCACGCCGA CGGTCAGCCA GCGCCCGCTG TTGATGGTGC
	CGCCGTGCAT

14501	CAACAAGTTC TACATCCTCG ACCTGCAACC GGAAAATTCG
	CTGGTGCGCT

14551	ACGCGGTGGA GCAGGGCAAC ACCGTGTTCC TGATCTCGTG
	GAGCAATCCG

14601	GACAAGTCGC TGGCCGGCAC CACCTGGGAC GACTACGTGG
	AGCAGGGCGT

14651	GATCGAAGCG ATCCGCATCG TCCAGGACGT CAGCGGCCAG
	GACAAGCTGA

14701	ACATGTTCGG CTTCTGCGTG GGCGGCACCA TCGTTGCCAC
	CGCACTGGCG

14751	GTACTGGCGG CGCGTGGCCA GCACCCGGCG GCCAGCCTGA
	CCCTGCTGAC

14801	CACCTTCCTC GACTTCAGCG ACACCGGCGT GCTCGACGTC
	TTCGTCGATG

14851	AAACCCAGGT CGCGCTGCGT GAACAGCAAT TGCGCGATGG
	CGGCCTGATG

14901	CCGGGCCGTG ACCTGGCCTC GACCTTCTCG AGCCTGCGTC
	CGAACGACCT

14951	GGTATGGAAC TATGTGCAGT CGAACTACCT CAAAGGCAAT
	GAGCCGGCGG

15001	CGTTTGACCT GCTGTTCTGG AATTCGGACA GCACCAATTT
	GCCGGGCCCG

15051	ATGTTCTGCT GGTACCTGCG CAACACCTAC CTGGAAAACA
	GCCTGAAAGT

15101	GCCGGGCAAG CTGACGGTGG CCGGCGAAAA GATCGACCTC
	GGCCTGATCG

15151	ACGCCCCGGC CTTCATCTAC GGTTCGCGCG AAGACCACAT
	CGTGCCGTGG

15201	ATGTCGGCGT ACGGTTCGCT CGACATCCTC AACCAGGGCA
	AGCCGGGCGC

15251	CAACCGCTTC GTGCTGGGCG CGTCCGGCCA TATCGCCGGC
	GTGATCAACT

15301	CGGTGGCCAA GAACAAGCGC AGCTACTGGA TCAACGACGG
	TGGCGCCGCC

15351	GATGCCCAGG CCTGGTTCGA TGGCGCGCAG GAAGTGCCGG
	GCAGCTGGTG

15401	GCCGCAATGG GCCGGGTTCC TGACCCAGCA TGGCGGCAAG
	AAGGTCAAGC

15451	CCAAGGCCAA GCCCGGCAAC GCCCGCTACA CCGCGATCGA
	GGCGGCGCCC

15501	GGCCGTTACG TCAAAGCCAA GGGCTGAGCG GCCGCTGAGT
	AATTCTGATA

15551	TTAGAGGGAG CATTAATGTG TTGTTGTGAT GTGGTTTATA
	TGGGGAAATT

15601	AAATAAATGA TGTATGTACC TCTTGCCTAT GTAGGTTTGT
	GTGTTTTGTT

15651	TTGTTGTCTA GCTTTGGTTA TTAAGTAGTA GGGACGTTCG
	TTCGTGTCTC

15701	AAAAAAAGGG GTACTACCAC TCTGTAGTGT ATATGGATGC
	TGGAAATCAA

15751	TGTGTTTTGT ATTTGTTCAC CTCCATTGTT GAATTCAATG
	TCAAATGTGT

15801	TTTGCGTTGG TTATGTGTAA AATTACTATC TTTCTCGTCC
	GATGATCAAA

15851	GTTTTAAGCA ACAAAACCAA GGGTGAAATT TAAACTGTGC
	TTTGTTGAAG

15901	ATTCTTTTAT CATATTGAAA ATCAAATTAC TAGCAGCAGA
	TTTTACCTAG

15951	CATGAAATTT TATCAACAGT ACAGCACTCA CTAACCAAGT
	TCCAAACTAA

16001	GATGCGCCAT TAACATCAGC CAATAGGCAT TTTCAGCAAG
	GCGCGCCCGC

16051	GCCGATGTAT GTGACAACCC TCGGGATTGT TGATTTATTT
	CAAAACTAAG

16101	AGTTTTTGTC TTATTGTTCT CGTCTATTTT GGATATCAAT
	CTTAGTTTTA

16151	TATCTTTTCT AGTTCTCTAC GTGTTAAATG TTCAACACAC
	TAGCAATTTG

16201	GCCTGCCAGC GTATGGATTA TGGAACTATC AAGTCTGTGA
	CGCGCCGTAC

16251	GTAGTGTTTA TCTTTGTTGC TTTTCTGAAC AATTTATTTA
	CTATGTAAAT

16301	ATATTATCAA TGTTTAATCT ATTTTAATTT GCACATGAAT
	TTTCATTTTA

16351	TTTTTACTTT ACAAAACAAA TAAATATATA TGCAAAAAAA
	TTTACAAACG

16401	ATGCACGGGT TACAAACTAA TTTCATTAAA TGCTAATGCA
	GATTTTGTGA

16451	AGTAAAACTC CAATTATGAT GAAAAATACC ACCAACACCA
	CCTGCGAAAC

16501	TGTATCCCAA CTGTCCTTAA TAAAAATGTT AAAAAGTATA
	TTATTCTCAT

16551	TTGTCTGTCA TAATTTATGT ACCCCACTTT AATTTTTCTG
	ATGTACTAAA

16601	CCGAGGGCAA ACTGAAACCT GTTCCTCATG CAAAGCCCCT
	ACTCACCATG

16651	TATCATGTAC GTGTCATCAC CCAACAACTC CACTTTTGCT
	ATATAACAAC

16701	ACCCCCGTCA CACTCTCCCT CTCTAACACA CACCCCACTA
	ACAATTCCTT

16751	CACTTGCAGC ACTGTTGCAT CATCATCTTC ATTGCAAAAC
	CCTAAACTTC

16801	ACCTTCAACC GCGGCCGCAT GGCTTCTATG ATATCCTCTT
	CCGCTGTGAC

16851	AACAGTCAGC CGTGCCTCTA GGGGGCAATC CGCCGCAGTG
	GCTCCATTCG

16901	GCGGCCTCAA ATCCATGACT GGATTCCCAG TGAAGAAGGT
	CAACACTGAC

16951	ATTACTTCCA TTACAAGCAA TGGTGGAAGA GTAAAGTGCA
	TGCAGGTGTG

17001	GCCTCCAATT GGAAAGAAGA AGTTTGAGAC TCTTTCCTAT
	TTGCCACCAT

17051	TGACGAGAGA TTCTAGAGTG ACTCAGCGCA TTGCGTATGT
	GACCGGCGGC

17101	ATGGGTGGTA TCGGAACCGC CATTTGCCAG CGGCTGGCCA
	AGGATGGCTT

17151	TCGTGTGGTG GCCGGTTGCG GCCCCAACTC GCCGCGCCGC
	GAAAAGTGGC

17201	TGGAGCAGCA GAAGGCCCTG GGCTTCGATT TCATTGCCTC
	GGAAGGCAAT

17251	GTGGCTGACT GGGACTCGAC CAAGACCGCA TTCGACAAGG
	TCAAGTCCGA

17301	GGTCGGCGAG GTTGATGTGC TGATCAACAA CGCCGGTATC
	ACCCGCGACG

17351	TGGTGTTCCG CAAGATGACC CGCGCCGACT GGGATGCGGT
	GATCGACACC

17401	AACCTGACCT CGCTGTTCAA CGTCACCAAG CAGGTGATCG
	ACGGCATGGC

17451	CGACCGTGGC TGGGGCCGCA TCGTCAACAT CTCGTCGGTG
	AACGGGCAGA

17501	AGGGCCAGTT CGGCCAGACC AACTACTCCA CCGCCAAGGC
	CGGCCTGCAT

17551	GGCTTCACCA TGGCACTGGC GCAGGAAGTG GCGACCAAGG
	GCGTGACCGT

17601	CAACACGGTC TCTCCGGGCT ATATCGCCAC CGACATGGTC
	AAGGCGATCC

17651	GCCAGGACGT GCTCGACAAG ATCGTCGCGA CGATCCCGGT
	CAAGCGCCTG

17701	GGCCTGCCGG AAGAGATCGC CTCGATCTGC GCCTGGTTGT
	CGTCGGAGGA

17751	GTCCGGTTTC TCGACCGGCG CCGACTTCTC GCTCAACGGC
	GGCCTGCATA

17801	TGGGCTGAGC GGCCGCTGAG TAATTCTGAT ATTAGAGGGA
	GCATTAATGT

17851	GTTGTTGTGA TGTGGTTTAT ATGGGGAAAT TAAATAAATG
	ATGTATGTAC

17901	CTCTTGCCTA TGTAGGTTTG TGTGTTTTGT TTTGTTGTCT
	AGCTTTGGTT

17951	ATTAAGTAGT AGGGACGTTC GTTCGTGTCT CAAAAAAAGG
	GGTACTACCA

18001	CTCTGTAGTG TATATGGATG CTGGAAATCA ATGTGTTTTG
	TATTTGTTCA

18051	CCTCCATTGT TGAATTCAAT GTCAAATGTG TTTTGCGTTG
	GTTATGTGTA

18101	AAATTACTAT CTTTCTCGTC CGATGATCAA AGTTTTAAGC
	AACAAAACCA

18151	AGGGTGAAAT TTAAACTGTG CTTTGTTGAA GATTCTTTTA
	TCATATTGAA

18201	AATCAAATTA CTAGCAGCAG ATTTTACCTA GCATGAAATT
	TTATCAACAG

18251	TACAGCACTC ACTAACCAAG TTCCAAACTA AGATGCGCCA
	TTAACATCAG

18301	CCAATAGGCA TTTTCAGCAA GGCGCGTAA

Claims

We claim:

1. A transgenic plant comprising:

(a) one or more nucleotide sequences encoding one or more enzymes for producing polyhydroxyalkanoate (PHA) in the transgenic plant, and

(b) one or more nucleotide sequences selected from the group consisting of:

(i) a nucleotide sequence encoding a small interfering RNA (siRNA) specific for the one or more nucleotide sequences encoding the one or more enzymes for producing PHA in the transgenic plant wherein the expression of the nucleotide sequences encoding the siRNA is under the control of an inducible regulatory element, and

(ii) a nucleotide sequence encoding one or more PHA degradation enzymes, wherein the expression of the one or more PHA degradation enzymes is under the control of an inducible regulatory element or germination specific regulatory element.

2. The transgenic plant of claim 1 wherein the transgenic plant produces seeds.

3. The transgenic plant of claim 2 wherein the seeds comprise oilseeds.

4. The transgenic plant of claim 1 wherein one or more of the nucleotide sequences encoding the one or more enzymes for producing polyhydroxyalkanoate (PHA) is under the control of a seed specific promoter.

5. The transgenic plant of claim 1 wherein the siRNA inhibits expression of phaA, phaB or phaC in the transgenic plant.

6. A transgenic plant or seed comprising a nucleotide sequence of a vector selected from the group consisting of phaA-RNAi/35S; phaC-RNAi/35S; phaA-RNAi/gly; and phaC-RNAi/gly.

7. The transgenic plant of claim 1 wherein seeds of the transgenic plant produce PHA.

8. The transgenic plant of claim 7 wherein one or more seeds produced by the plant comprise up to 12.32% PHA dry weight of the seed.

9. The transgenic plant of claim 1 wherein one or more seeds produced by the transgenic plant are capable of germinating.

10. The transgenic plant of claim 1 further comprising one or more transgenes selected from the group consisting of sedoheptulose 1,7-bisphosphatase (SBPase, EC 3.1.3.37), fructose 1,6-bisphosphatase (FBPase, EC 3.1.3.11), and a bi-functional enzyme encoding both SBPase and FBPase, that increase carbon flow through the Calvin cycle.

11. The transgenic plant claim 10 wherein the bifunctional enzyme is isolated from an organism selected from the group consisting of Ralstonia eutropha H16, Synechococcus elongatus PCC 7942, Synechococcus sp. WH 7805, Butyrivibrio crossotus DSM 2876, Rothia mucilaginosa DY-18, Thiobacillus denitrificans ATCC 25259, Methylacidiphilum infernorum V4, Nitrosomonas europaea ATCC 19718, Vibrio vulnificus CMCP6, and Methanohalophilus mahii DSM 5219.

12. A method for producing transgenic plants engineered to produce PHA comprising:

(a) genetically engineering the transgenic plant to express a nucleotide sequence under the control of an inducible regulatory element or germination specific regulatory element, wherein the nucleotide sequence is selected from the group consisting of: (i) a nucleotide sequence encoding siRNA for one or more genes encoding enzymes for producing PHA in the transgenic plant, and (ii) a nucleotide sequence encoding one or more PHA degradation enzymes, and

(b) inducing expression of the nucleotide sequences during germination.

13. A nucleic acid construct comprising a nucleotide sequence of a vector selected from the group consisting of phaA-RNAi/35S; phaC-RNAi/35S; phaA-RNAi/gly; and phaC-RNAi/gly.

14. The transgenic plant of claim 1 wherein the plant is selected from the group consisting of B. napus, B. rappa, B. carinata, B. juncea, Camelina sativa, Crambe, jatropha, castor, Cuphea, Calendula, Arabidopsis thaliana, maize, soybean, cottonseed, sunflower, palm, coconut, safflower, peanut, Sinapis alba, sugarcane and flax.

15. The transgenic plant of claim 1 further comprising a transketolase (EC 2.2.1.1).

16. The transgenic plant of claim 1 further comprising an aldolase (EC 4.1.2.13).

17. The method of claim 12 wherein siRNA expression is induced by soaking seeds of the transgenic plant in an inducing agent.